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+<body>
+<h1>The Project Gutenberg eBook, Volcanoes: Past and Present, by Edward Hull</h1>
+<pre>
+This eBook is for the use of anyone anywhere at no cost and with
+almost no restrictions whatsoever.  You may copy it, give it away or
+re-use it under the terms of the Project Gutenberg License included
+with this eBook or online at <a href = "http://www.gutenberg.org">www.gutenberg.org</a></pre>
+<p>Title: Volcanoes: Past and Present</p>
+<p>Author: Edward Hull</p>
+<p>Release Date: March 13, 2010  [eBook #31627]</p>
+<p>Language: English</p>
+<p>Character set encoding: ISO-8859-1</p>
+<p>***START OF THE PROJECT GUTENBERG EBOOK VOLCANOES: PAST AND PRESENT***</p>
+<p>&nbsp;</p>
+<h3>E-text prepared by Steven Gibbs, Stephen H. Sentoff,<br />
+    and the Project Gutenberg Online Distributed Proofreading Team<br />
+    (http://www.pgdp.net)</h3>
+<p>&nbsp;</p>
+<hr class="full" />
+<p>&nbsp;</p>
+<p>&nbsp;</p>
+<p>&nbsp;</p>
+
+<p class="center"><span class="pagenum"><a name="Page_i" id="Page_i">[Pg i]</a></span>
+<i>THE CONTEMPORARY SCIENCE SERIES.</i></p>
+
+<p class="center"><span class="smcap">Edited by</span> HAVELOCK ELLIS.</p>
+
+<hr />
+
+
+<h1>VOLCANOES:<br />
+
+PAST AND PRESENT.</h1>
+
+<p><span class="pagenum"><a name="Page_ii" id="Page_ii">[Pg ii]</a></span></p>
+<hr class="major" />
+<div class="figcenter">
+<a name="FIGURE_1">
+  <img src="images/figure1.jpg" alt="Eruption of Vesuvius" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 1.</span>&mdash;Eruption of Vesuvius, 1872-1873
+<br /><i>(From a Photograph by Negretti and Zambra).</i>
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_iii" id="Page_iii">[Pg iii]</a></span></p>
+<hr class="major" />
+<h1>VOLCANOES:<br />
+PAST AND PRESENT.
+</h1>
+<hr />
+<h3>BY</h3>
+<h2>EDWARD HULL, M.A., LL.D., F.R.S.</h2>
+<p class="center"><i>Examiner in Geology to the University of London.</i></p>
+<hr />
+
+<p class="center">WITH 41 ILLUSTRATIONS AND 4 PLATES
+OF ROCK-SECTIONS.</p>
+<hr />
+
+<p class="center">LONDON:<br/>
+WALTER SCOTT, <span class="smcap">Limited</span>,<br />
+24, WARWICK LANE, PATERNOSTER ROW.</p>
+
+<p class="center">1892.
+</p>
+
+
+
+<p><span class="pagenum"><a name="Page_v" id="Page_v">[Pg v]</a></span></p>
+<hr class="major" />
+<p><i>By THE SAME AUTHOR.</i></p>
+
+<blockquote><p><b>The Coal-fields of Great Britain: their
+History, Structure, and Resources.</b> 4th edit. (1881.) E.
+Stanford.</p>
+
+<p><b>The Physical History of the British Isles.</b>
+With a Dissertation on the Origin of Western Europe and of
+the Atlantic Ocean. (1882.) E. Stanford.</p>
+
+<p><b>The Physical Geology and Geography of
+Ireland.</b> 2nd edit. (1891.) E. Stanford.</p>
+
+<p><b>Treatise on the Building and Ornamental
+Stones of Great Britain and Foreign Countries.</b> (1872.)
+Macmillan and Co.</p>
+
+<p><b>Memoir on the Physical Geology and
+Geography of Arabia-Petræa, Palestine, and adjoining Districts.</b>
+(1886.) Committee of the Palestine Exploration Fund.</p>
+
+<p><b>Mount Seir, Sinai, and Western Palestine.</b>
+Being a Narrative of a Scientific Expedition, 1883-84. (1885.)
+Committee of the Palestine Exploration Fund.</p>
+
+<p><b>Text-book of Physiography.</b> (1888.) C. W.
+Deacon and Co.</p>
+
+<p><b>Sketch of Geological History.</b> (1887.) C. W.
+Deacon and Co.</p></blockquote>
+
+<p><span class="pagenum"><a name="Page_vii" id="Page_vii">[Pg vii]</a></span></p>
+
+<hr class="major" />
+<h2><a name="PREFACE" id="PREFACE"></a>PREFACE.</h2>
+
+
+<p>It has not been my object to present in the following
+pages even an approximately complete description
+of the volcanic and seismic phenomena of the globe;
+such an undertaking would involve an amount of
+labour which few would be bold enough to attempt;
+nor would it be compatible with the aims of the
+<i>Contemporary Science Series</i>.</p>
+
+<p>I have rather chosen to illustrate the most recent
+conclusions regarding the phenomena and origin of
+volcanic action, by the selection of examples drawn
+from the districts where these phenomena have been
+most carefully observed and recorded under the light
+of modern geological science. I have also endeavoured
+to show, by illustrations carried back into later geological
+epochs, how the volcanic phenomena of the
+present day do not differ in kind, though they may
+in degree, from those of the past history of our globe.
+For not only do the modes of eruption of volcanic
+materials in past geological times resemble those of
+the present or human epoch, but the materials themselves
+<span class="pagenum"><a name="Page_viii" id="Page_viii">[Pg viii]</a></span>are so similar in character that it is only in
+consequence of alterations in structure or composition
+which the original materials have undergone, since
+their extrusion, that any important distinctions can
+be recognised between the volcanic products of recent
+times and those of earlier periods.</p>
+
+<p>I have, finally, endeavoured to find an answer to
+two interesting and important questions: (1) Are we
+now living in an epoch of extraordinary volcanic
+energy?&mdash;a question which such terrible outbursts
+as we have recently witnessed in Japan, the Malay
+Archipelago, and even in Italy, naturally suggest;
+and (2) What is the ultimate cause of volcanic
+action? On this latter point I am gratified to find
+that my conclusions are in accordance with those
+expounded by one who has been appropriately
+designated "the Nestor of Modern Geology," Professor
+Prestwich.</p>
+
+<p>Within the last few years the study of the structure
+and composition of volcanic rocks, by means of the
+microscope brought to bear on their translucent
+sections, has added wonderfully to our knowledge
+of such rocks, and has become a special branch of
+petrological investigation. Commenced by Sorby,
+and carried on by Allport, Zirkel, Rosenbusch, Von
+Lasaulx, Teall, and many more enthusiastic students,
+it has thrown a flood of light upon our knowledge of
+the mutual relations of the component minerals of
+igneous masses, the alteration these minerals have
+undergone in some cases, and the conditions under
+<span class="pagenum"><a name="Page_ix" id="Page_ix">[Pg ix]</a></span>which they have been erupted and consolidated. But
+nothing that has been observed has tended materially
+to alter conclusions arrived at by other processes of
+reasoning regarding volcanic phenomena, and for
+these we have to fall back upon observations conducted
+in the field on a more or less large scale,
+and carried on before, during, and after eruptions.
+Macroscopic and microscopic observations have to
+go hand in hand in the study of volcanic phenomena.</p>
+
+<p class="closing">
+E. H.
+</p>
+
+<p><span class="pagenum"><a name="Page_xi" id="Page_xi">[Pg xi]</a></span></p>
+
+<hr class="major" />
+<h2><a name="CONTENTS" id="CONTENTS"></a>CONTENTS.</h2>
+
+
+
+
+<div class="center">
+<table border="0" cellpadding="4" cellspacing="0" summary="">
+<tr><td align="center" colspan="3"><b>PART I.</b></td></tr>
+<tr><td align="center" colspan="3"><i>INTRODUCTION.</i></td></tr>
+<tr><td align="right"></td><td align="left"></td><td align="right">PAGE</td></tr>
+<tr><td align="right"><span class="smcap">Chap. I.</span></td>
+  <td align="left"><a href="#PART_I_CHAPTER_I"><span class="smcap">Historic Notices of Volcanic Action</span></a></td><td align="right">1-9</td></tr>
+<tr><td align="right"> " II.</td>
+  <td align="left"><a href="#PART_I_CHAPTER_II"><span class="smcap">Form, Structure, and Composition of Volcanic Mountains</span></a></td><td align="right">10-19</td></tr>
+<tr><td align="right"> " III.</td>
+  <td align="left"><a href="#PART_I_CHAPTER_III"><span class="smcap">Lines and Groups of Active Volcanic Vents</span></a></td><td align="right">20-29</td></tr>
+<tr><td align="right"> " IV.</td>
+  <td align="left"><a href="#PART_I_CHAPTER_IV"><span class="smcap">Mid-ocean Volcanic Islands</span></a></td><td align="right">30-40</td></tr>
+<tr><td align="center" colspan="3"><b>PART II.</b></td></tr>
+<tr><td align="center" colspan="3"><i>EUROPEAN VOLCANOES.</i></td></tr>
+<tr><td align="right"><span class="smcap">Chap. I.</span></td>
+  <td align="left"><a href="#PART_II_CHAPTER_I"><span class="smcap">Vesuvius</span></a></td><td align="right">41-60</td></tr>
+<tr><td align="right">" II.</td>
+  <td align="left"><a href="#PART_II_CHAPTER_II"><span class="smcap">Etna</span></a></td><td align="right">61-68</td></tr>
+<tr><td align="right">" III.</td>
+  <td align="left"><a href="#PART_II_CHAPTER_III"><span class="smcap">The Lipari Islands, Stromboli</span></a></td><td align="right">69-75</td></tr>
+<tr><td align="right">" IV.</td>
+  <td align="left"><a href="#PART_II_CHAPTER_IV"><span class="smcap">The Santorin Group</span></a></td><td align="right">76-83</td></tr>
+<tr><td align="right">" V.</td>
+  <td align="left"><a href="#PART_II_CHAPTER_V"><span class="smcap">European Extinct or Dormant Volcanoes</span></a></td><td align="right">84-91</td></tr>
+<tr><td align="right">" VI.</td>
+  <td align="left"><a href="#PART_II_CHAPTER_VI"><span class="smcap">Extinct Volcanoes of Central France</span></a></td><td align="right">92-112</td></tr>
+<tr><td align="right">" VII.</td>
+  <td align="left"><a href="#PART_II_CHAPTER_VII"><span class="smcap">The Volcanic District of the Rhine Valley</span></a></td><td align="right">13-125</td></tr>
+<tr><td align="center" colspan="3"><b>PART III.</b></td></tr>
+<tr><td align="center" colspan="3"><i>DORMANT OR MORIBUND VOLCANOES OF OTHER PARTS OF THE WORLD.</i></td></tr>
+<tr><td align="right"><span class="smcap">Chap. I.</span></td>
+  <td align="left"><a href="#PART_III_CHAPTER_I"><span class="smcap">Dormant Volcanoes of Palestine and Arabia</span></a></td><td align="right">126-135</td></tr>
+<tr><td align="right">" II.</td>
+  <td align="left"><a href="#PART_III_CHAPTER_II"><span class="smcap">The Volcanic Regions of North America</span></a></td><td align="left">136-145</td></tr>
+<tr><td align="right">" III.</td>
+  <td align="left"><a href="#PART_III_CHAPTER_III"><span class="smcap">Volcanoes of New Zealand</span></a></td><td align="right">146-153</td></tr>
+<tr><td align="center" colspan="3"><span class="pagenum"><a name="Page_xii" id="Page_xii">[Pg xii]</a></span><b>PART IV.</b></td></tr>
+<tr><td align="center" colspan="3"><i>TERTIARY VOLCANIC DISTRICTS OF THE BRITISH ISLES.</i></td></tr>
+<tr><td align="right"><span class="smcap">Chap. I.</span></td>
+  <td align="left"><a href="#PART_IV_CHAPTER_I"><span class="smcap">Antrim</span></a></td><td align="right">154-159</td></tr>
+<tr><td align="right">" II.</td>
+  <td align="left"><a href="#PART_IV_CHAPTER_II"><span class="smcap">Succession of Volcanic Eruptions</span></a></td><td align="right">160-171</td></tr>
+<tr><td align="right">" III.</td>
+  <td align="left"><a href="#PART_IV_CHAPTER_III"><span class="smcap">Island of Mull and Adjoining Coast</span></a></td><td align="right">172-176</td></tr>
+<tr><td align="right">" IV.</td>
+  <td align="left"><a href="#PART_IV_CHAPTER_IV"><span class="smcap">Isle of Skye</span></a></td><td align="right">177-179</td></tr>
+<tr><td align="right">" V.</td>
+  <td align="left"><a href="#PART_IV_CHAPTER_V"><span class="smcap">The Scuir of Eigg</span></a></td><td align="right">180-184</td></tr>
+<tr><td align="right">" VI.</td>
+  <td align="left"><a href="#PART_IV_CHAPTER_VI"><span class="smcap">Isle of Staffa</span></a></td><td align="right">185-186</td></tr>
+<tr><td align="center" colspan="3"><b>PART V.</b></td></tr>
+<tr><td align="center" colspan="3"><i>PRE-TERTIARY VOLCANIC ROCKS.</i></td></tr>
+<tr><td align="right"><span class="smcap">Chap. I.</span></td>
+  <td align="left"><a href="#PART_V_CHAPTER_I"><span class="smcap">The Deccan Trap-series of India</span></a></td><td align="left">187-189</td></tr>
+<tr><td align="right">" II.</td>
+  <td align="left"><a href="#PART_V_CHAPTER_II"><span class="smcap">Abyssinian Table-lands</span></a></td><td align="right">190-193</td></tr>
+<tr><td align="right">" III.</td>
+  <td align="left"><a href="#PART_V_CHAPTER_III"><span class="smcap">Cape Colony</span></a></td><td align="right">194-195</td></tr>
+<tr><td align="right">" IV.</td>
+  <td align="left"><a href="#PART_V_CHAPTER_IV"><span class="smcap">Volcanic Rocks of Past Geological Periods of the British Isles</span></a></td><td align="left">196-199</td></tr>
+<tr><td align="center" colspan="3"><b>PART VI.</b></td></tr>
+<tr><td align="center" colspan="3"><i>SPECIAL VOLCANIC AND SEISMIC PHENOMENA.</i></td></tr>
+<tr><td align="right"><span class="smcap">Chap. I.</span></td>
+  <td align="left"><a href="#PART_VI_CHAPTER_I"><span class="smcap">The Eruption of Krakatoa in 1883</span></a></td><td align="right">201-216</td></tr>
+<tr><td align="right">" II.</td>
+  <td align="left"><a href="#PART_VI_CHAPTER_II"><span class="smcap">Earthquakes</span></a></td><td align="right">217-224</td></tr>
+<tr><td align="center" colspan="3"><b>PART VII.</b></td></tr>
+<tr><td align="center" colspan="3"><i>VOLCANIC AND SEISMIC PROBLEMS.</i></td></tr>
+<tr><td align="right"><span class="smcap">Chap. I.</span></td>
+  <td align="left"><a href="#PART_VII_CHAPTER_I"><span class="smcap">The Ultimate Cause of Volcanic Action</span></a></td><td align="right">225-235</td></tr>
+<tr><td align="right">" II.</td>
+  <td align="left"><a href="#PART_VII_CHAPTER_II"><span class="smcap">Lunar Volcanoes</span></a></td><td align="right">236-252</td></tr>
+<tr><td align="right">" III.</td>
+  <td align="left"><a href="#PART_VII_CHAPTER_III"><span class="smcap">Are we Living in an Epoch of Special Volcanic Activity?</span></a></td><td align="right">253-257</td></tr>
+<tr><td align="center" colspan="3"><b>APPENDIX.</b></td></tr>
+<tr><td align="left" colspan="2"><a href="#APPENDIX"><span class="smcap">A Brief Account of the Principal Varieties of Volcanic Rocks</span></a></td><td align="right">259-265</td></tr>
+<tr><td align="left" colspan="2"><a href="#INDEX"><span class="smcap">Index</span></a></td><td align="right">268</td></tr>
+</table></div>
+
+<p><span class="pagenum"><a name="Page_xiii" id="Page_xiii">[Pg xiii]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="ILLUSTRATIONS" id="ILLUSTRATIONS"></a>ILLUSTRATIONS.</h2>
+
+
+<div class="center">
+<table border="0" cellpadding="4" cellspacing="0" summary="">
+<tr><td align="right"><span class="smcap">Fig. 1.</span></td>
+  <td align="left"><a href="#FIGURE_1">
+    <span class="smcap">Eruption of Vesuvius, 1872-73</span></a></td>
+  <td align="right"><i>Frontispiece</i></td></tr>
+<tr><td align="right">" 2.</td>
+  <td align="left"><a href="#FIGURE_2">
+    <span class="smcap">Cotopaxi</span></a></td>
+  <td align="right"><i>Page</i> 16</td></tr>
+<tr><td align="right">" 3.</td>
+  <td align="left"><a href="#FIGURE_3">
+    <span class="smcap">Volcanic Cone of Orizaba</span></a></td>
+  <td align="right">" 21</td></tr>
+<tr><td align="right"></td>
+  <td align="left"><a href="#MAP_1">
+    <span class="smcap">Map of the World, showing Active and Extinct Volcanoes</span></a></td>
+  <td align="right">" 23</td></tr>
+<tr><td align="right">" 4.</td>
+  <td align="left"><a href="#FIGURE_4">
+    <span class="smcap">Teneriffe, seen from the Ocean</span></a></td>
+  <td align="right">" 31</td></tr>
+<tr><td align="right">" 5.</td>
+  <td align="left"><a href="#FIGURE_5">
+    <span class="smcap">View of the Summit of Teneriffe</span></a></td>
+  <td align="right">" 35</td></tr>
+<tr><td align="right">" 6.</td>
+  <td align="left"><a href="#FIGURE_6">
+    <span class="smcap">Probable Aspect of Vesuvius at Beginning of Christian Era</span></a></td>
+  <td align="right">" 43</td></tr>
+<tr><td align="right">" 7.</td>
+  <td align="left"><a href="#FIGURE_7">
+    <span class="smcap">View of Vesuvius before 1767</span></a></td>
+  <td align="right">" 50</td></tr>
+<tr><td align="right">" 8.</td>
+  <td align="left"><a href="#FIGURE_8">
+    <span class="smcap">Map of District bordering Bay of Naples</span></a></td>
+  <td align="right">" 52</td></tr>
+<tr><td align="right">" 9.</td>
+  <td align="left"><a href="#FIGURE_9">
+    <span class="smcap">View of Vesuvius in 1872</span></a></td>
+  <td align="right">" 53</td></tr>
+<tr><td align="right">" 10.</td>
+  <td align="left"><a href="#FIGURE_10">
+    <span class="smcap">Ideal Section through Etna</span></a></td>
+  <td align="right">" 63</td></tr>
+<tr><td align="right">" 11.</td>
+  <td align="left"><a href="#FIGURE_11">
+    <span class="smcap">Map of the Lipari Islands</span></a></td>
+  <td align="right">" 70</td></tr>
+<tr><td align="right">" 12.</td>
+  <td align="left"><a href="#FIGURE_12">
+    <span class="smcap">The Island of Vulcano in Eruption</span></a></td>
+  <td align="right">" 71</td></tr>
+<tr><td align="right">" 13.</td>
+  <td align="left"><a href="#FIGURE_13">
+    <span class="smcap">Ideal Section through Gulf of Santorin</span></a></td>
+  <td align="right">" 76</td></tr>
+<tr><td align="right">" 14.</td>
+  <td align="left"><a href="#FIGURE_14">
+    <span class="smcap">Bird's-eye View of Gulf of Santorin</span></a></td>
+  <td align="right">" 79</td></tr>
+<tr><td align="right">" 15.</td>
+  <td align="left"><a href="#FIGURE_15">
+    <span class="smcap">Ground Plan of Rocca Monfina</span></a></td>
+  <td align="right">" 80</td></tr>
+<tr><td align="right">" 16.</td>
+  <td align="left"><a href="#FIGURE_16">
+    <span class="smcap">Geological Section of Tiber Valley at Rome</span></a></td>
+  <td align="right">" 88</td></tr>
+<tr><td align="right">" 17.</td>
+  <td align="left"><a href="#FIGURE_17">
+    <span class="smcap">Generalised Section Through the Vale of Clermont</span></a></td>
+  <td align="right">" 93</td></tr>
+<tr><td align="right"><span class="pagenum"><a name="Page_xiv" id="Page_xiv">[Pg xiv]</a></span><span class="smcap">Fig. 18.</span></td>
+  <td align="left"><a href="#FIGURE_18">
+    <span class="smcap">View of Puy de Dôme and Neighbouring Volcanoes</span></a></td>
+  <td align="right"><i>Page</i> 95</td></tr>
+<tr><td align="right">" 19.</td>
+  <td align="left"><a href="#FIGURE_19">
+    <span class="smcap">Mont Demise, seen from the S.E.</span></a></td>
+  <td align="right">" 103</td></tr>
+<tr><td align="right">" 20.</td>
+  <td align="left"><a href="#FIGURE_20">
+    <span class="smcap">Sketch Map of Rhenish Area in the Miocene Epoch</span></a></td>
+  <td align="right">" 114</td></tr>
+<tr><td align="right">" 21.</td>
+  <td align="left"><a href="#FIGURE_21">
+    <span class="smcap">The Volcanic Range of the Siebengebirge</span></a></td>
+  <td align="right">" 117</td></tr>
+<tr><td align="right">" 22.</td>
+  <td align="left"><a href="#FIGURE_22">
+    <span class="smcap">Section of Extinct Crater of the Roderberg</span></a></td>
+  <td align="right">" 120</td></tr>
+<tr><td align="right">" 23.</td>
+  <td align="left"><a href="#FIGURE_23">
+    <span class="smcap">Plan and Section of the Laacher See</span></a></td>
+  <td align="right">" 122</td></tr>
+<tr><td align="right">" 24.</td>
+  <td align="left"><a href="#FIGURE_24">
+    <span class="smcap">Extinct Craters in the Jaulân</span></a></td>
+  <td align="right">" 130</td></tr>
+<tr><td align="right">" 25.</td>
+  <td align="left"><a href="#FIGURE_25">
+    <span class="smcap">Mount Shasta</span></a></td>
+  <td align="right">" 139</td></tr>
+<tr><td align="right">" 26.</td>
+  <td align="left"><a href="#FIGURE_26">
+    <span class="smcap">Forms of Volcanic Tuff-Cones, Auckland</span></a></td>
+  <td align="right">" 148</td></tr>
+<tr><td align="right">" 27.</td>
+  <td align="left"><a href="#FIGURE_27">
+    <span class="smcap">"The White Rocks," Portrush, Co. Antrim</span></a></td>
+  <td align="right">" 157</td></tr>
+<tr><td align="right">" 28.</td>
+  <td align="left"><a href="#FIGURE_28">
+    <span class="smcap">Section across the Volcanic Plateau of Antrim</span></a></td>
+  <td align="right">" 159</td></tr>
+<tr><td align="right">" 29.</td>
+  <td align="left"><a href="#FIGURE_29">
+    <span class="smcap">Section at Templepatrick</span></a></td>
+  <td align="right">" 161</td></tr>
+<tr><td align="right">" 30.</td>
+  <td align="left"><a href="#FIGURE_30">
+    <span class="smcap">Cliff above the Giant's Causeway</span></a></td>
+  <td align="right">" 163</td></tr>
+<tr><td align="right">" 31.</td>
+  <td align="left"><a href="#FIGURE_31">
+    <span class="smcap">The Giant's Causeway, Co. Antrim</span></a></td>
+  <td align="right">" 165</td></tr>
+<tr><td align="right">" 32.</td>
+  <td align="left"><a href="#FIGURE_32">
+    <span class="smcap">"The Chimneys," North Coast of Antrim</span></a></td>
+  <td align="right">" 166</td></tr>
+<tr><td align="right">" 33.</td>
+  <td align="left"><a href="#FIGURE_33">
+    <span class="smcap">Section at Alt na Searmoin, Mull</span></a></td>
+  <td align="right">" 175</td></tr>
+<tr><td align="right">" 34.</td>
+  <td align="left"><a href="#FIGURE_34">
+    <span class="smcap">View of the Scuir of Eigg from the East</span></a></td>
+  <td align="right">" 181</td></tr>
+<tr><td align="right"></td>
+  <td align="left"><a href="#MAP_2">
+    <span class="smcap">Map of Volcanic Band of the Moluccas</span></a></td>
+  <td align="right">" 200</td></tr>
+<tr><td align="right">" 35.</td>
+  <td align="left"><a href="#FIGURE_35">
+    <span class="smcap">Map of the Krakatoa Group of Islands</span></a></td>
+  <td align="right">" 203</td></tr>
+<tr><td align="right">" 36.</td>
+  <td align="left"><a href="#FIGURE_36">
+    <span class="smcap">Section from Verlaten Island through Krakatoa</span></a></td>
+  <td align="right">" 204</td></tr>
+<tr><td align="right"><span class="pagenum"><a name="Page_xv" id="Page_xv">[Pg xv]</a></span><span class="smcap">Fig. 37.</span></td>
+  <td align="left"><a href="#FIGURE_37">
+    <span class="smcap">Isoseismals of the Charleston Earthquake</span></a></td>
+  <td align="right"><i>Page</i> 223</td></tr>
+<tr><td align="right">" 38.</td>
+  <td align="left"><a href="#FIGURE_38">
+    <span class="smcap">Photograph of the Moon's Surface</span></a></td>
+  <td align="right">" 241</td></tr>
+<tr><td align="right">" 39.</td>
+  <td align="left"><a href="#FIGURE_39">
+    <span class="smcap">Portion of the Moon's Surface</span></a></td>
+  <td align="right">" 243</td></tr>
+<tr><td align="right"><i>PLATES.</i></td></tr>
+<tr><td align="right">I. &amp; II.</td>
+  <td align="left"><a href="#PLATE_1">
+    <span class="smcap">Magnified Sections of Vesuvian Lavas.</span></a></td>
+  </tr>
+<tr><td align="right">III. &amp; IV.</td>
+  <td align="left"><a href="#PLATE_3">
+    <span class="smcap">Magnified Sections of Volcanic Rocks.</span></a></td>
+  </tr>
+</table></div>
+
+<p><span class="pagenum"><a name="Page_1" id="Page_1">[Pg 1]</a></span></p>
+
+<hr class="major" />
+<h1>Volcanoes: Past and Present.</h1>
+
+
+
+<hr class="major" />
+<h1><a name="PART_I" id="PART_I"></a>PART I.
+<br /><br />
+INTRODUCTION.</h1>
+
+
+
+<hr class="major" />
+<h2><a name="PART_I_CHAPTER_I" id="PART_I_CHAPTER_I"></a>CHAPTER I.
+<br /><br />
+HISTORIC NOTICES OF VOLCANIC ACTION.</h2>
+
+
+<p>There are no manifestations of the forces of Nature
+more calculated to inspire us with feelings of awe
+and admiration than volcanic eruptions preceded or
+accompanied, as they generally are, by earthquake
+shocks. Few agents have been so destructive in
+their effects; and to the real dangers which follow
+such terrestrial convulsions are to be added the
+feelings of uncertainty and revulsion which arise from
+the fact that the earth upon which we tread, and
+which we have been accustomed to regard as the
+emblem of stability, may become at any moment the
+agent of our destruction. It is, therefore, not surprising
+that the ancient Greeks, who, as well as the
+Romans, were close observers of the phenomena of
+Nature, should have investigated the causes of terrestrial
+disturbances, and should have come to some
+<span class="pagenum"><a name="Page_2" id="Page_2">[Pg 2]</a></span>conclusions upon them in accordance with the light
+they possessed. These terrible forces presented to
+the Greeks, who clothed all the operations of Nature
+in poetic imagery and deified her forces, their poetical
+and mystical side; and as there was a deity for every
+natural force, so there was one for earthquakes and
+volcanoes. Vulcan, the deformed son of Juno (whose
+name bears so strange a resemblance to that of "the
+first artificer in iron" of the Bible, Tubal Cain), is
+condemned to pass his days under Mount Etna,
+fabricating the thunderbolts of Jove, and arms for
+the gods and great heroes of antiquity.</p>
+
+<p>The Pythagoreans appear to have held the doctrine
+of a central fire
+(<span title="Greek: meson pyr" class="greek">&#956;&#941;&#963;&#959;&#957; &#960;&#8166;&#961;</span>)
+as the source of volcanic
+phenomena; and in the Dialogues of Plato allusion
+is made to a subterranean reservoir of lava, which,
+according to Simplicius, was in accordance with
+the doctrine of the Pythagoreans which Plato was
+recounting.<a name="FNanchor_1_1" id="FNanchor_1_1"></a><a href="#Footnote_1_1" class="fnanchor">[1]</a> Thucydides clearly describes the effect
+of earthquakes upon coast-lines of the Grecian Archipelago,
+similar to that which took place in the case of
+the earthquake of Lisbon, the sea first retiring and
+afterwards inundating the shore. Pliny supposed
+that it was by earthquake avulsion that islands were
+naturally formed. Thus Sicily was torn from Italy,
+Cyprus from Syria, Eub&#339;a from B&#339;otia, and the rest;
+but this view was previously enunciated by Aristotle
+in his
+"<span title="Greek: Peri kosmou" class="greek">&#928;&#949;&#961;&#953; &#954;&#959;&#963;&#956;&#959;&#965;</span>,"
+where he states that earthquakes
+have torn to pieces many parts of the earth, while
+lands have been converted into sea, and that tracts
+once covered by the sea have been converted into
+dry land.</p>
+
+<p><span class="pagenum"><a name="Page_3" id="Page_3">[Pg 3]</a></span></p><p>But the most philosophical views regarding terrestrial
+phenomena are those given by Ovid as having
+been held by Pythagoras (about <span class="smcap">B.C.</span> 580). In the
+<i>Metamorphoses</i> his views regarding the interchange
+of land and sea, the effects of running water in
+eroding valleys, the growth of deltas, the effect of
+earthquakes in burying cities and diverting streams
+from their sources, are remarkable anticipations of
+doctrines now generally held.<a name="FNanchor_2_2" id="FNanchor_2_2"></a><a href="#Footnote_2_2" class="fnanchor">[2]</a> But what most concerns
+us at present are his views regarding the
+changes which have come over volcanic mountains. In
+his day Vesuvius was dormant, but Etna was active;
+so his illustrations are drawn from the latter mountain;
+and in this connection he observes that volcanic vents
+shift their position. There was a time, he says, when
+Etna was not a burning mountain, and the time will
+come when it will cease to burn; whether it be that
+some caverns become closed up by the movements
+of the earth, or others opened, or whether the fuel
+is finally exhausted.<a name="FNanchor_3_3" id="FNanchor_3_3"></a><a href="#Footnote_3_3" class="fnanchor">[3]</a> Strabo may be regarded as
+<span class="pagenum"><a name="Page_4" id="Page_4">[Pg 4]</a></span>having originated the view, now generally held, that
+active volcanoes are safety-valves to the regions in
+which they are situated. Referring to the tradition
+recorded by Pliny, that Sicily was torn from Italy by
+an earthquake, he observes that the land near the sea
+in those parts was rarely shaken by earthquakes, since
+there are now orifices whereby fire and ignited matters
+and waters escape; but formerly, when the volcanoes
+of Etna, the Lipari Islands, Ischia, and others were
+closed up, the imprisoned fire and wind might have
+produced far more violent movements.<a name="FNanchor_4_4" id="FNanchor_4_4"></a><a href="#Footnote_4_4" class="fnanchor">[4]</a></p>
+
+<p>The account of the first recorded eruption of
+Vesuvius has been graphically related by the younger
+Pliny in his two letters to Tacitus, to which I shall
+have occasion to refer further on.<a name="FNanchor_5_5" id="FNanchor_5_5"></a><a href="#Footnote_5_5" class="fnanchor">[5]</a> These bring down
+the references to volcanic phenomena amongst ancient
+authors to the commencement of the Christian era;
+from all of which we may infer that the more
+enlightened philosophers of antiquity had a general
+idea that eruptions had their origin in a central fire
+within the interior of the earth, that volcanic mountains
+were liable to become dormant for long periods,
+and afterwards to break out into renewed activity,
+that there existed a connection between volcanic
+action and earthquakes, and that volcanoes are safety-valves
+for the regions around.</p>
+
+<p>It is unnecessary that I should pursue the historical
+sketch further. Those who wish to know the views
+of writers of the Middle Ages will find them recorded
+<span class="pagenum"><a name="Page_5" id="Page_5">[Pg 5]</a></span>by Sir Charles Lyell.<a name="FNanchor_6_6" id="FNanchor_6_6"></a><a href="#Footnote_6_6" class="fnanchor">[6]</a> The long controversy carried
+on during the latter part of the eighteenth century
+between "Neptunists," led by Werner on the one
+side, and "Vulcanists," led by Hutton and Playfair
+on the other, regarding the origin of such rocks as
+granite and basalt, was finally brought to a close by the
+triumph of the "Vulcanists," who demonstrated that
+such rocks are the result of igneous fusion; and that
+in the cases of basalt and its congeners, they are being
+extruded from volcanic vents at the present day.
+The general principles for the classification of rocks
+as recognised in modern science may be regarded as
+having been finally established by James Hutton, of
+Edinburgh, in his <i>Theory of the Earth</i>,<a name="FNanchor_7_7" id="FNanchor_7_7"></a><a href="#Footnote_7_7" class="fnanchor">[7]</a> while they
+were illustrated and defended by Professor Playfair in
+his work entitled, <i>Illustrations of the Huttonian Theory
+of the Earth</i>,<a name="FNanchor_8_8" id="FNanchor_8_8"></a><a href="#Footnote_8_8" class="fnanchor">[8]</a> although other observers, such as
+Desmarest, Collini, and Guettard, had in other
+countries come to very clear views on this subject.</p>
+
+<p>The following are some of the more important
+works on the phenomena of volcanoes and earthquakes
+published during the present century:&mdash;<a name="FNanchor_9_9" id="FNanchor_9_9"></a><a href="#Footnote_9_9" class="fnanchor">[9]</a></p>
+
+<p>1. Poulett Scrope, F.R.S., <i>Considerations on Volcanoes</i>
+(1825). This work is dedicated to Lyell, his
+fellow-worker in the same department of science, and
+was undertaken, as he says, "in order to help to
+dispel that signal delusion as to the mode of action
+of the subtelluric forces with which the Elevation-Crater
+theory had mystified the geological world."
+The second edition was published in 1872.</p>
+
+<p><span class="pagenum"><a name="Page_6" id="Page_6">[Pg 6]</a></span></p><p>2. This was followed by the admirable work, <i>On
+the Extinct Volcanoes of Central France</i>, published in
+1826 (2nd edition, 1858), and is one of the most complete
+monographs on a special volcanic district ever
+written.</p>
+
+<p>3. Dr. Samuel Hibbert, <i>History of the Extinct Volcanoes
+of the Basin of Neuwied on the Lower Rhine</i>
+(1832). Dr. Hibbert's work is one of remarkable
+merit, if we consider the time at which it was written.
+For not only does it give a clear and detailed account
+of the volcanic phenomena of the Eifel and the Lower
+Rhine, but it anticipates the principles upon which
+modern writers account for the formation of river
+valleys and other physical features; and in working
+out the physical history of the Rhine valley below
+Mainz, and its connection with the extinct volcanoes
+which are found on both banks of that river, he has
+taken very much the same line of reasoning which
+was some years afterwards adopted by Sir A. Ramsay
+when dealing with the same subject. It does not
+appear that the latter writer was aware of Dr.
+Hibbert's treatise.</p>
+
+<p>4. Leopold von Buch, <i>Description Physique des Iles
+Canaries</i> (1825), translated from the original by C.
+Boulanger (1836); <i>Geognostische Reise</i> (Berlin, 1809),
+2 vols.; and <i>Reise durch Italien</i> (1809). From a large
+number of writings on volcanoes by this distinguished
+traveller, whom Alexander von Humboldt calls "dem
+geistreichen Forscher der Natur," the above are
+selected as being the most important. That on the
+Canaries is accompanied by a large atlas, in which
+the volcanoes of Teneriffe, Palma, and Lancerote,
+with some others, are elaborately represented, and
+are considered to bear out the author's views regarding
+<span class="pagenum"><a name="Page_7" id="Page_7">[Pg 7]</a></span>the formation of volcanic cones by elevation or
+upheaval. The works dealing with the volcanic
+phenomena of Central and Southern Italy are also
+written with the object, in part at least, of illustrating
+and supporting the same theoretical views; with
+these we have to deal in the next chapter.</p>
+
+<p>5. Dr. Charles Daubeny, F.R.S., <i>Description of Active
+and Extinct Volcanoes, of Earthquakes, and of Thermal
+Springs, with remarks on the causes of these phenomena,
+the character of their respective products, and their
+influence on the past and present condition of the globe</i>
+(2nd edition, 1848). In this work the author gives
+detailed descriptions of almost all the known volcanic
+districts of the globe, and defends what is called "the
+chemical theory of volcanic action"&mdash;a theory at one
+time held by Sir Humphrey Davy.</p>
+
+<p>6. Wolfgang Sartorius von Waltershausen, <i>Der
+Ætna</i>. This work possesses a melancholy interest
+from the fact that its distinguished author did not
+live to see its publication. Von Waltershausen, having
+spent several years in making an elaborate survey of
+Etna, produced an atlas containing numerous detailed
+maps, views, and drawings of this mountain and its
+surroundings, which were published at Weimar by
+Engelmann in 1858. A description in MS. to accompany
+the atlas was also prepared, but before it was
+printed, the author died, on the 16th October 1876.
+The MS. having been put into the hands of the late
+Professor Arnold von Lasaulx by the publisher of
+the atlas, it was subsequently brought out under the
+care of this distinguished petrologist, who was so
+fully fitted for an undertaking of this kind.</p>
+
+<p>7. Sir Charles Lyell in his <i>Principles of Geology</i><a name="FNanchor_10_10" id="FNanchor_10_10"></a><a href="#Footnote_10_10" class="fnanchor">[10]</a>
+<span class="pagenum"><a name="Page_8" id="Page_8">[Pg 8]</a></span>devotes several chapters to the consideration of
+volcanic phenomena, in which, being in harmony
+with the views of his friend, Poulett Scrope, he combats
+the "elevation theory" of Von Buch, as applied
+to the formation of volcanic mountains, holding that
+they are built up of ashes, stones, and scoriæ blown
+out of the throat of the volcano and piled around
+the orifice in a conical form. Together with these
+materials are sheets of lava extruded in a molten
+condition from the sides or throat of the crater itself.</p>
+
+<p>8. Professor J. W. Judd, F.R.S., in his able work
+entitled, <i>Volcanoes: What they are, and what they
+teach</i>,<a name="FNanchor_11_11" id="FNanchor_11_11"></a><a href="#Footnote_11_11" class="fnanchor">[11]</a> has furnished the student of vulcanicity with a
+very complete manual of a general character on the
+subject. The author, having extensive personal
+acquaintance with the volcanoes of the south of
+Europe and the volcanic rocks of the British Isles,
+was well equipped for undertaking a work of the
+kind; and in it he supports the views of Lyell and
+Scrope regarding the mode of formation of volcanic
+mountains.</p>
+
+<p>9. Sir Archibald Geikie, F.R.S., in his elaborate
+monograph<a name="FNanchor_12_12" id="FNanchor_12_12"></a><a href="#Footnote_12_12" class="fnanchor">[12]</a> on the Tertiary Volcanic Rocks of the
+British Isles, has recorded his views regarding the
+origin and succession of the plateau basalts and
+associated rocks over the region extending from the
+north of Ireland to the Inner Hebrides; and in
+dealing with these districts in the following pages I
+have made extensive use of his observations and
+conclusions.</p>
+
+<p>10. <i>Report published by the Royal Society on the
+Eruption of Krakatoa</i><span class="pagenum"><a name="Page_9" id="Page_9">[Pg 9]</a></span>&mdash;drawn up by several authors
+(1885)&mdash;and the work on the same subject by Chev.
+Verbeek, and published by the Government of the
+Netherlands (1886). In these works all the phenomena
+connected with the extraordinary eruptions of
+Krakatoa in 1883 are carefully noted and scientifically
+discussed, and illustrated by maps and drawings.</p>
+
+<p>11. <i>The Charleston Earthquake of August 31, 1886</i>,
+by Captain Clarence Edward Dutton, U.S. Ordnance
+Corps. Ninth Annual Report of the United States
+Geological Survey, 1887-88, with maps and illustrations.</p>
+
+<p>12. Amongst other works which may be consulted
+with advantage is that of Mr. T. Mellard Reade on
+<i>The Origin of Mountain Ranges</i>; the Rev. Osmond
+Fisher's <i>Physics of the Earth</i>; Professor G. H.
+Darwin and Mr. C. Davison on "The Internal Tension
+of the Earth's Crust," <i>Philosophical Transactions of the
+Royal Society</i>, vol. 178; Mr. R. Mallet, "On the
+Dynamics of Earthquakes," <i>Trans. Roy. Irish Academy</i>,
+vol. xxi.; Professor O'Reilly's "Catalogues of Earthquakes,"
+<i>Trans. Roy. Irish Academy</i>, vol. xxviii.
+(1884 and 1888); and Mr. A. Ent. Gooch <i>On the Causes
+of Volcanic Action</i> (London, 1890). These and other
+authorities will be referred to in the text.</p>
+
+<div class="footnote"><p><a name="Footnote_1_1" id="Footnote_1_1"></a><a href="#FNanchor_1_1"><span class="label">[1]</span></a> See Julius Schwarez <i>On the Failure of Geological Attempts made by
+the Greeks</i>. (Edition 1888.)</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_2" id="Footnote_2_2"></a><a href="#FNanchor_2_2"><span class="label">[2]</span></a></p>
+<div class="poem">
+<span class="i0">"Vidi ego, quod fuerat quondam solidissima tellus,<br /></span>
+<span class="i0">Esse fretum. Vidi factas ex æquore terras:<br /></span>
+<span class="i0">Et procul à pelago conchæ jacuere marinæ;<br /></span>
+<span class="i0">Et vetus inventa est in montibus anchora sumnis.<br /></span>
+<span class="i0">Quodque fuit campus, vallem de cursus aquarum<br /></span>
+<span class="i0">Fecit; et eluvie mons est deductus in æquor:<br /></span>
+<span class="i0">Eque paludosa siccis humus aret arenis;<br /></span>
+<span class="i0">Quæque sitim tulerant, stagnata paludibus hument.<br /></span>
+<span class="i0">Hic fontes Natura novos emissit, at illuc<br /></span>
+<span class="i0">Clausit: et antiquis concussa tremoribus orbis<br /></span>
+<span class="i0">Fulmina prosiliunt...."<br /></span>
+</div>
+<p style="margin-top:0em;"><span class="closing">&mdash;Lib. xv. 262.</span>
+</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_3" id="Footnote_3_3"></a><a href="#FNanchor_3_3"><span class="label">[3]</span></a></p>
+<div class="poem">
+<span class="i0">"Nec, quæ sulfureis ardet fornacibus, Ætne<br /></span>
+<span class="i0">Ignea semper erit; neque enim fuit ignea semper.<br /></span>
+<span class="i0">Nam, sive est animal tellus, et vivit, habetque<br /></span>
+<span class="i0">Spiramenta locis flammam exhalantia multis;<br /></span>
+<span class="i0">Spirandi mutare vias, quotiesque movetur,<br /></span>
+<span class="i0">Has finire potest, illas aperire cavernas:<br /></span>
+<span class="i0">Sive leves imis venti cohibentur in antris;<br /></span>
+<span class="i0">Saxaque cum saxis...."<br /></span>
+</div>
+<p style="margin-top:0em;"><span class="closing">&mdash;<i>Ibid.</i>, 340.</span>
+</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_4" id="Footnote_4_4"></a><a href="#FNanchor_4_4"><span class="label">[4]</span></a> Strabo, lib. vi.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_5" id="Footnote_5_5"></a><a href="#FNanchor_5_5"><span class="label">[5]</span></a> Tacitus, lib. vi. 16, 20.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_6" id="Footnote_6_6"></a><a href="#FNanchor_6_6"><span class="label">[6]</span></a> <i>Principles of Geology</i>, 11th edition, vol. i., ch. 3.</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_7" id="Footnote_7_7"></a><a href="#FNanchor_7_7"><span class="label">[7]</span></a> 2 vols., Edin. (1795).</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_8" id="Footnote_8_8"></a><a href="#FNanchor_8_8"><span class="label">[8]</span></a> Edin. (1802).</p></div>
+
+<div class="footnote"><p><a name="Footnote_9_9" id="Footnote_9_9"></a><a href="#FNanchor_9_9"><span class="label">[9]</span></a> A more extended list of early works will be found in Daubeny's
+<i>Volcanoes</i> (1848).</p></div>
+
+<div class="footnote"><p><a name="Footnote_10_10" id="Footnote_10_10"></a><a href="#FNanchor_10_10"><span class="label">[10]</span></a> 11th edition (1872).</p></div>
+
+<div class="footnote"><p><a name="Footnote_11_11" id="Footnote_11_11"></a><a href="#FNanchor_11_11"><span class="label">[11]</span></a> 4th edition (1888).</p></div>
+
+<div class="footnote"><p><a name="Footnote_12_12" id="Footnote_12_12"></a><a href="#FNanchor_12_12"><span class="label">[12]</span></a> "The History of Volcanic Action during the Tertiary Period in
+the British Isles," <i>Trans. Roy. Soc., Edin.</i> Vol. xxxv, (1888).</p></div>
+<p><span class="pagenum"><a name="Page_10" id="Page_10">[Pg 10]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_I_CHAPTER_II" id="PART_I_CHAPTER_II"></a>CHAPTER II.
+<br /><br />
+FORM, STRUCTURE, AND COMPOSITION OF
+VOLCANIC MOUNTAINS.</h2>
+
+
+<p>The conical form of a volcanic mountain is so
+generally recognised, that many persons who have no
+intelligent acquaintance with geological phenomena
+are in the habit of attributing to all mountains having
+a conical form, and especially if accompanied by a
+truncated apex, a volcanic origin. Yet this is very far
+from being the fact, as some varieties of rock, such as
+quartzite, not unfrequently assume this shape. Of
+such we have an example in the case of Errigal,
+a quartzite mountain in Donegal, nearly 3000
+feet high, which bears a very near approach in form
+to a perfect cone or pyramid, and yet is in no way
+connected, as regards its origin or structure, with
+volcanic phenomena. Another remarkable instance
+is that of Schehallion in Scotland, also composed
+of quartz-rock; and others may be found amongst
+the ranges of Islay and Jura, described by Sir A.
+Geikie.<a name="FNanchor_1_13" id="FNanchor_1_13"></a><a href="#Footnote_1_13" class="fnanchor">[1]</a></p>
+
+<p>Notwithstanding, however, such exceptions, which
+might be greatly multiplied, the majority of cone-shaped
+mountains over the globe have a volcanic
+<span class="pagenum"><a name="Page_11" id="Page_11">[Pg 11]</a></span>origin.<a name="FNanchor_2_14" id="FNanchor_2_14"></a><a href="#Footnote_2_14" class="fnanchor">[2]</a> The origin of this form in each case is
+entirely distinct. In the case of quartzite mountains,
+the conical form is due to atmospheric influences
+acting on a rock of uniform composition, traversed by
+numerous joints and fissures crossing each other at
+obtuse angles, along which the rock breaks up and falls
+away, so that the sides are always covered by angular
+shingle forming slopes corresponding to the angle of
+friction of the rock in question. In the case of a
+volcanic mountain, however, the same form is due
+either to accumulation of fragmental material piled
+around the cup-shaped hollow, or crater, which is
+usually placed at the apex of the cone, and owing
+to which it is bluntly terminated, or else to the welling
+up from beneath of viscous matter in the manner
+presently to be described.</p>
+
+<p><i>Views of Sir Humphrey Davy and L. von Buch.</i>&mdash;The
+question how a volcanic cone came to be
+formed was not settled without a long controversy
+carried on by several naturalists of eminence. Some
+of the earlier writers of modern times on the subject
+of vulcanicity&mdash;such as Sir Humphrey Davy and
+Leopold von Buch&mdash;maintained that the conical
+form was due to upheaval by a force acting from
+below at a central focus, whereby the materials
+of which the mountain is formed were forced to
+assume a <i>quâ-quâ versal</i> position&mdash;that is, a position
+in which the materials dip away from the central
+focus in every direction. But this view, originally
+<span class="pagenum"><a name="Page_12" id="Page_12">[Pg 12]</a></span>contested by Scrope and Lyell, has now been
+generally abandoned. It will be seen on reflection
+that if a series of strata of ashes, tuff, and lava,
+originally horizontal, or nearly so, were to be forced
+upwards into a conical form by a central force, the
+result would be the formation of a series of radiating
+fissures ever widening from the circumference towards
+the focus. In the case of a large mountain such
+fissures, whether filled with lava or otherwise, would
+be of great breadth towards the focus, or central
+crater, and could not fail to make manifest beyond
+dispute their mechanical origin. But no fissures of
+the kind here referred to are, as a matter of fact, to be
+observed. Those which do exist are too insignificant
+and too irregular in direction to be ascribed to such
+an origin; so that the views of Von Buch and Davy
+must be dismissed, as being unsupported by observation,
+and as untenable on dynamical grounds. As a
+matter of fact, the "elevatory theory," or the "elevation-crater
+theory," as it is called by Scrope, has been
+almost universally abandoned by writers on vulcanicity.</p>
+
+<p><i>Principal Varieties of Volcanic Mountains as regards
+Form.</i>&mdash;But whilst rejecting the "elevatory theory," it
+is necessary to bear in mind that volcanic cones and
+dome-shaped elevations have been formed in several
+distinct ways, giving rise to varieties of structure essentially
+different. Two of the more general of these
+varieties of form, the crater-cone and the dome, are
+found in some districts, as in Auvergne, side by side.
+The crater-cone consists of beds or sheets of ashes,
+lapilli, and slag piled up in a conical form, with a central
+crater (or cup) containing the principal pipe through
+which these materials have been erupted; the dome,
+<span class="pagenum"><a name="Page_13" id="Page_13">[Pg 13]</a></span>of a variety of trachytic lava, which has been extruded
+in a molten, or viscous, condition from a central pipe,
+and in such cases there is no distinct crater. There
+are other forms of volcanic mountains, such as those
+built up of basaltic matter, of which I shall have to
+speak hereafter, but the two former varieties are the
+most prevalent; and we may now proceed to consider
+the conditions under which the crater-cone volcanoes
+have been formed.</p>
+
+<p><i>Crateriform Volcanic Cones.</i>&mdash;Of this class nearly
+all the active volcanoes of the Mediterranean region&mdash;Etna,
+Vesuvius, Stromboli, and the Lipari Islands&mdash;may
+be considered as representatives. They consist
+essentially of masses of fragmental material, which
+have from time to time been blown out of an orifice
+and piled up around with more or less regularity
+(according to the force exerted, and direction of
+the prevalent winds), alternating with sheets of lava.
+In this way mountains several thousand feet in height
+and of vast horizontal extent are formed. The fragmental
+materials thus accumulated are of all sizes,
+from the finest dust up to blocks many tons in weight,
+the latter being naturally piled around nearest to
+the orifice. The fine dust, blown high into the air
+by the explosive force of the gases and vapours, is
+often carried to great distances by the prevalent
+winds. Thus during the eruption of Vesuvius in <span class="smcap">A.D.</span>
+472 showers of ashes, carried high into the air by the
+westerly wind, fell over Constantinople at a distance
+of 750 miles.<a name="FNanchor_3_15" id="FNanchor_3_15"></a><a href="#Footnote_3_15" class="fnanchor">[3]</a></p>
+
+<p><span class="pagenum"><a name="Page_14" id="Page_14">[Pg 14]</a></span></p><p>These loose, or partially consolidated, fragmental
+materials are rudely stratified, and slope downwards
+and outwards from the edge of the crater, so as to
+present the appearance of what is known as "the
+dip" of stratified deposits which have been upraised
+from the horizontal position by terrestrial forces. It
+was this excentrical arrangement which gave rise to
+the supposition that such volcanic ash-beds had been
+tilted up by a force acting in the direction of the
+volcanic throat, or orifice of eruption. The interior
+wall of Monte di Somma, the original crater of
+Vesuvius, presents a good illustration of such fragmental
+beds. I shall have occasion further on to
+describe more fully the structure of this remarkable
+mountain; so that it will suffice to say here that this
+old prehistoric crater, the walls of which enclose the
+modern cone of Vesuvius, is seen to be formed of
+irregular beds of ash, scoriæ, and fragmental masses,
+traversed by numerous dykes of lava, and sloping
+away outwards towards the surrounding plains.</p>
+
+<p>Of similar materials are the flanks of Etna composed,
+even at great distances from the central crater;
+the beds of ash and agglomerate sometimes alternating
+with sheets of solidified lava and traversed
+by dykes of similar material of later date, injected
+from below through fissures formed during periods of
+eruptive energy. Numerous similar examples are to
+be observed in the Auvergne region of Central France
+and the Eifel. And here we find remarkable cases of
+"breached cones," or craters, which will require some
+special description. Standing on the summit of the
+Puy de Dôme, and looking northwards or southwards,
+the eye wanders over a tract formed of dome-shaped
+hills and of extinct crater-cones rising from
+<span class="pagenum"><a name="Page_15" id="Page_15">[Pg 15]</a></span>a granitic platform. But what is most peculiar in
+the scene is the ruptured condition of a large number
+of the cones with craters. In such cases the wall of
+the crater has been broken down on one side, and we
+observe that a stream of lava has been poured out
+through the breach and overflowed the plain below.
+The cause of this breached form is sufficiently obvious.
+In such cases there has been an explosion of ashes,
+stones, and scoriæ from the volcanic throat, by which
+a cone-shaped hill with a crater has been built up.
+This has been followed by molten lava welling up
+through the throat, and gradually filling the crater.
+But, as the lava is much more dense than the material
+of which the crater wall is composed, the pressure
+of the lava outwards has become too great for the
+resistance of the wall, which consequently has given
+way at its weakest part and, a breach being formed,
+the molten matter has flowed out in a stream which
+has inundated the country lying at the base of the
+cone. In one instance mentioned by Scrope, the
+original upper limit of the lake of molten lava has
+left its mark in the form of a ring of slag on the
+inside of the breached crater.<a name="FNanchor_4_16" id="FNanchor_4_16"></a><a href="#Footnote_4_16" class="fnanchor">[4]</a></p>
+
+<p><i>Craterless Domes.</i>&mdash;These differ essentially both in
+form and composition from those just described,
+and have their typical representatives in the
+Auvergne district, though not without their analogues
+elsewhere, as in the case of Chimborazo, in
+South America, one of the loftiest volcanic mountains
+in the world.</p>
+
+<p><span class="pagenum"><a name="Page_16" id="Page_16">[Pg 16]</a></span></p>
+<div class="figcenter">
+<a name="FIGURE_2">
+  <img src="images/figure2.jpg" alt="Cotopaxi" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 2.</span>&mdash;Cotopaxi, a volcano of the Cordilleras of Quito, still active,
+and covered by snow down to a level of 14,800 feet. Below this is a
+zone of naked rock, succeeded by another of forest vegetation. Owing
+to the continuous extrusion of lava from the crater, the cone is being
+gradually built up of fresh material, and the crater is comparatively small
+in consequence.&mdash;(A diagrammatic view after A. von Humboldt.)
+</td></tr>
+</table>
+</div>
+
+<p>Taking the Puy de Dôme, Petit Suchet, Cliersou,
+Grand Sarcoui in Auvergne, and the Mamelon in the
+Isle of Bourbon as illustrations, we have in all these
+cases a group of volcanic hills, dome-shaped and
+destitute of craters, the summits being rounded or
+slightly flattened. We also observe that the flanks
+rise more abruptly from their bases, and contrast in
+outline with the graceful curve of the crater cones.
+<span class="pagenum"><a name="Page_17" id="Page_17">[Pg 17]</a></span>The dome-shaped volcanoes are generally composed of
+felsitic matter, whether domite, trachyte, or andesite,
+which has been extruded in a molten or viscous
+condition from some orifice or fissure in the earth's
+crust, and being piled up and spreading outwards,
+necessarily assumes such a form as that of a dome,
+as has been shown by experiment on a small scale by
+Dr. E. Reyer, of Grätz.<a name="FNanchor_5_17" id="FNanchor_5_17"></a><a href="#Footnote_5_17" class="fnanchor">[5]</a> The contrast between the
+two forms (those of the dome and the crater-cone) is
+exemplified in the case of the Grand Sarcoui and its
+neighbours. The former is composed of a species of
+trachyte; the latter of ashes and fragmental matter
+which have been blown out of their respective vents of
+eruption into the air, and piled up and around in a
+crateriform manner with sides of gradually diminishing
+slope outwards, thus giving rise to the characteristic
+volcanic curve. The two varieties here
+referred to, contrasting in form, composition, and
+colour of material, can be clearly recognised from the
+summit of the Puy de Dôme, which rises by a head
+and shoulders above its fellows, and thus affords an
+advantageous standpoint from which to compare the
+various forms of this remarkable group of volcanic
+mountains.</p>
+
+<p>Cotopaxi (<a href="#FIGURE_2">Fig. 2</a>) has been generally supposed to be
+a dome; but Whymper, who ascended the mountain
+in 1880, shows that it is a cone with a crater, 2,300
+feet in largest diameter. He determined the height to
+be 19,613 feet above the ocean. Its real elevation
+above the sea is somewhat masked, owing to the fact
+that it rises from the high plain of Tapia, which is
+<span class="pagenum"><a name="Page_18" id="Page_18">[Pg 18]</a></span>itself 8,900 feet above the sea surface. The smaller
+peak on the right (<a href="#FIGURE_2">Fig. 2</a>) is that of Carihuairazo,
+which reaches an elevation of over 16,000 feet.</p>
+
+<p>Chimborazo, in Columbia, province of Quito, is one
+of the loftiest of the chain of the Andes, and is
+situated in lat. 1° 30' S., long. 78° 58' W. Though not
+in a state of activity, it is wholly composed of volcanic
+material, and reaches an elevation of over 20,000 feet
+above the ocean; its sides being covered by a sheet
+of permanent snow to a level of 2,600 feet below the
+summit.<a name="FNanchor_6_18" id="FNanchor_6_18"></a><a href="#Footnote_6_18" class="fnanchor">[6]</a> Seen from the shores of the Pacific, after
+the long rains of winter, it presents a magnificent
+spectacle, "when the transparency of the air is
+increased, and its enormous circular summit is seen
+projected upon the deep azure blue of the equatorial
+sky. The great rarity of the air through which the
+tops of the Andes are seen adds much to the splendour
+of the snow, and aids the magical effect of its
+reflection."</p>
+
+<p>Chimborazo was ascended by Humboldt and Bonpland
+in 1802 almost to the summit; but at a height
+of 19,300 feet by barometrical measurement, their
+further ascent was arrested by a wide chasm. Boussingault,
+in company with Colonel Hall, accomplished
+the ascent as far as the foot of the mass of columnar
+"trachyte," the upper surface of which, covered
+by a dome of snow, forms the summit of the mountain.
+The whole mass of the mountain consists
+of volcanic rock, varieties of andesite; there is no
+trace of a crater, nor of any fragmental materials,
+<span class="pagenum"><a name="Page_19" id="Page_19">[Pg 19]</a></span>such as are usually ejected from a volcanic vent of
+eruption.<a name="FNanchor_7_19" id="FNanchor_7_19"></a><a href="#Footnote_7_19" class="fnanchor">[7]</a></p>
+
+<p><i>Lava Crater-Cones.</i>&mdash;A third form of volcanic
+mountain is that which has been built up by successive
+eruptions of basic lava, such as basalt or dolerite,
+when in a molten condition. These are very rare,
+and the slope of the sides depends on the amount of
+original viscosity. Where the lava is highly fused its
+slope will be slight, but if in a viscous condition,
+successive outpourings from the orifice, unable to
+reach the base of the mountain, will tend to form a
+cone with increasing slope upwards. Mauna Loa
+and Kilauea, in the Hawaiian Group, according to
+Professor J. D. Dana, are basalt volcanoes in a normal
+state. They have distinct craters, and the material
+of which the mountain is formed is basalt or dolerite.
+The volcano of Rangitoto in Auckland, New Zealand,
+appears to belong to this class.</p>
+
+<p>Basalt is the most fusible of volcanic rocks, owing
+to the augite and magnetite it contains, so that it
+spreads out with a very slight slope when highly
+fused. Trachyte, on the other hand, is the least
+fusible owing to the presence of orthoclase felspar, or
+quartz; so that the volcanic domes formed of this
+material stand at a higher angle from the horizon
+than those of basaltic cones.</p>
+
+<div class="footnote"><p><a name="Footnote_1_13" id="Footnote_1_13"></a><a href="#FNanchor_1_13"><span class="label">[1]</span></a> <i>Scenery and Geology of Scotland</i> (1865), p. 214.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_14" id="Footnote_2_14"></a><a href="#FNanchor_2_14"><span class="label">[2]</span></a> Humboldt says: "The form of isolated conical mountains, as
+those of Vesuvius, Etna, the Peak of Teneriffe, Tunguagua, and
+Cotopaxi, is certainly the shape most commonly observed in volcanoes
+all over the globe."&mdash;<i>Views of Nature</i>, translated by E. C. Otté and
+H. G. Bohn (1850).</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_15" id="Footnote_3_15"></a><a href="#FNanchor_3_15"><span class="label">[3]</span></a> It is supposed that after the disastrous explosion of Krakatoa in
+1883 the fine dust carried into the higher regions of the atmosphere
+was carried round almost the entire globe, and remained suspended for
+a lengthened period, as described in a future page.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_16" id="Footnote_4_16"></a><a href="#FNanchor_4_16"><span class="label">[4]</span></a> Another remarkable case is mentioned and figured by Judd, where
+one of the Lipari Isles, composed of pumice and rising out of the
+Mediterranean, has been breached by a lava-stream of obsidian.&mdash;<i>Loc.
+cit.</i>, p. 123.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_17" id="Footnote_5_17"></a><a href="#FNanchor_5_17"><span class="label">[5]</span></a> Reyer has produced such dome-shaped masses by forcing a quantity
+of plaster of Paris in a pasty condition up through an orifice in a board;
+referred to by Judd, <i>loc. cit.</i>, p. 125.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_18" id="Footnote_6_18"></a><a href="#FNanchor_6_18"><span class="label">[6]</span></a> Whymper determined the height to be 20,498 feet; Reiss and
+Stübel make it 20,703 feet. Whymper thinks there may be a crater
+concealed beneath the dome of snow.&mdash;<i>Travels amongst the Great
+Andes of the Equator</i>, by Edward Whymper (1892).</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_19" id="Footnote_7_19"></a><a href="#FNanchor_7_19"><span class="label">[7]</span></a> Whymper states that there is a prevalent idea that Cotopaxi and a
+volcano called Sangai act as safety-valves to each other. Sangai reaches
+an elevation (according to Reiss and Stübel) of 17,464 feet, and sends
+intermittent jets of steam high into the air, spreading out into vast
+cumulus clouds, which float away southwards, and ultimately disappear.&mdash;<i>Ibid.</i>,
+p. 73.</p></div>
+<p><span class="pagenum"><a name="Page_20" id="Page_20">[Pg 20]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_I_CHAPTER_III" id="PART_I_CHAPTER_III"></a>CHAPTER III.
+<br /><br />
+LINES AND GROUPS OF ACTIVE VOLCANIC VENTS.</h2>
+
+
+<p>The globe is girdled by a chain of volcanic
+mountains in a state of greater or less activity, which
+may perhaps be considered a girdle of safety for the
+whole world, through which the masses of molten
+matter in a state of high pressure beneath the crust
+find a way of escape; and thus the structure of the
+globe is preserved from even greater convulsions than
+those which from time to time take place at various
+points on its surface. This girdle is partly terrestrial,
+partly submarine; and commencing at Mount Erebus,
+near the Antarctic Pole, ranging through South
+Shetland Isle, Cape Horn, the Andes of South
+America, the Isthmus of Panama, then through
+Central America and Mexico, and the Rocky Mountains
+to Kamtschatka, the Aleutian Islands, the
+Kuriles, the Japanese, the Philippines, New Guinea,
+and New Zealand, reaches the Antarctic Circle by the
+Balleny Islands. This girdle sends off branches at
+several points. (See <a href="#MAP_1">Map, p. 23</a>.)</p>
+
+<p><span class="pagenum"><a name="Page_21" id="Page_21">[Pg 21]</a></span></p>
+
+<div class="figcenter">
+<a name="FIGURE_3">
+  <img src="images/figure3.jpg" alt="Volcanic cone of Orizaba" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 3.</span>&mdash;Volcanic cone of Orizaba (Cittaltepeth), in Mexico, now
+extinct; the upper part snow-clad, and at its base forest vegetation; it
+reaches a height of 16,302 Parisian feet above the sea.&mdash;(After A. von
+Humboldt.)
+</td></tr>
+</table>
+</div>
+
+
+<p>(<i>a.</i>) The linear arrangement of active or dormant
+volcanic vents has been pointed out by Humboldt,
+Von Buch, Daubeny, and other writers. The great
+range of burning mountains of the Andes of Chili,
+Peru, Bolivia, and Mexico, that of the Aleutian
+Islands, of Kamtschatka and the Kurile Islands,
+extending southwards into the Philippines, and the
+branching range of the Sunda Islands are well-known
+examples. That of the West Indian Islands,
+ranging from Grenada through St. Vincent, St.
+Lucia, Martinique, Dominica, Guadeloupe, Montserrat,
+Nevis, and St. Eustace,<a name="FNanchor_1_20" id="FNanchor_1_20"></a><a href="#Footnote_1_20" class="fnanchor">[1]</a> is also a remarkable
+example of the linear arrangement of volcanic
+<span class="pagenum"><a name="Page_22" id="Page_22">[Pg 22]</a></span>mountains. On tracing these ranges on a map
+of the world<a name="FNanchor_2_21" id="FNanchor_2_21"></a><a href="#Footnote_2_21" class="fnanchor">[2]</a> (<a href="#MAP_1">Map, p. 23</a>), it will be observed
+that they are either strings of islands, or lie in
+proximity to the ocean; and hence the view was
+naturally entertained by some writers that oceanic
+water, or at any rate that of a large lake or sea,
+was a necessary agent in the production of volcanic
+eruptions. This view seems to receive further corroboration
+from the fact that the interior portions
+of the continents and large islands such as Australia
+are destitute of volcanoes in action, with the remarkable
+exceptions of Mounts Kenia and Kilimanjaro in
+Central Africa, and a few others. It is also very
+significant in this connection that many of the
+volcanoes now extinct, or at least dormant, both in
+Europe and Asia, appear to have been in proximity
+to sheets of water during the period of activity.
+Thus the old volcanoes of the Haurân, east of the
+Jordan, appear to have been active at the period
+when the present Jordan valley was filled with water
+to such an extent as to constitute a lake two hundred
+miles in length, but which has now shrunk back to
+within the present limits of the Dead Sea.<a name="FNanchor_3_22" id="FNanchor_3_22"></a><a href="#Footnote_3_22" class="fnanchor">[3]</a> Again,
+at the period when the extinct volcanoes of Central
+France were in active operation, an extensive lake
+overspread the tract lying to the east of the granitic
+plateau on which the craters and domes are planted,
+now constituting the rich and fertile plain of Clermont.</p>
+
+<p><span class="pagenum"><a name="Page_23" id="Page_23">[Pg 23]</a></span></p>
+
+<div class="figcenter">
+<a name="MAP_1"></a>
+<a href="images/map1full.jpg">
+  <img src="images/map1.jpg" alt="Map of Volcanoes" />
+</a>
+</div>
+
+<p>Such instances are too significant to allow us to
+<span class="pagenum"><a name="Page_24" id="Page_24">[Pg 24]</a></span>doubt that water in some form is very generally
+connected with volcanic operations; but it does not
+follow that it was necessary to the original formation
+of volcanic vents, whether linear or sporadic. If
+this were so, the extinct volcanoes of the British
+Isles would still be active, as they are close to the
+sea-margin, and no volcano would now be active
+which is not near to some large sheet of water.
+But Jorullo, one of the great active volcanoes of
+Mexico, lies no less than 120 miles from the ocean,
+and Cotopaxi, in Ecuador, is nearly equally distant.
+Kilimanjaro, 18,881 feet high, and Kenia, in the
+equatorial regions of Central Africa, are about 150
+miles from the Victoria Nyanza, and a still greater
+distance from the ocean; and Mount Demavend, in
+Persia, which rises to an elevation of 18,464 feet near
+the southern shore of the Caspian Sea, a volcanic
+mountain of the first magnitude, is now extinct or
+dormant.<a name="FNanchor_4_23" id="FNanchor_4_23"></a><a href="#Footnote_4_23" class="fnanchor">[4]</a> Such facts as these all tend to show that
+although water may be an accessory of volcanic
+eruptions, it is not in all cases essential; and we
+are obliged, therefore, to have recourse to some other
+theory of volcanic action differing from that which
+would attribute it to the access of water to highly
+heated or molten matter within the crust of the earth.</p>
+
+<p>(<i>b.</i>) <i>Leopold von Buch on Rents and Fissures in the
+Earth's Crust.</i>&mdash;The view of Leopold von Buch, who
+considered that the great lines of volcanic mountains
+above referred to rise along the borders of rents, or
+fissures, in the earth's crust, is one which is inherently
+<span class="pagenum"><a name="Page_25" id="Page_25">[Pg 25]</a></span>probable, and is in keeping with observation. That
+the crust of the globe is to a remarkable extent
+fissured and torn in all directions is a phenomenon
+familiar to all field geologists. Such rents and fissures
+are often accompanied by displacement of the strata,
+owing to which the crust has been vertically elevated
+on one side or lowered on the other, and such displacements
+(or "faults") sometimes amount to thousands
+of feet. It is only occasionally, however, that such
+fractures are accompanied by the extrusion of molten
+matter; and in the North of England and Scotland
+dykes of igneous rock, such as basalt, which run
+across the country for many miles in nearly straight
+lines, often cut across the faults, and are only rarely
+coincident with them. Nevertheless, it can scarcely
+be a question that the grand chain of volcanic
+mountains which stretches almost continuously along
+the Andes of South America, and northwards through
+Mexico, has been piled up along the line of a system
+of fissures in the fundamental rocks parallel to the
+coast, though not actually coincident therewith.</p>
+
+<p>(<i>c.</i>) <i>The Cordilleras of Quito.</i>&mdash;The structure and
+arrangement of the Cordilleras of Quito, for example,
+are eminently suggestive of arrangement along lines
+of fissure. As shown by Alexander von Humboldt,<a name="FNanchor_5_24" id="FNanchor_5_24"></a><a href="#Footnote_5_24" class="fnanchor">[5]</a>
+the volcanic mountains are disposed in two parallel
+chains, which run side by side for a distance of over
+500 miles northwards into the State of Columbia, and
+enclose between them the high plains of Quito and
+Lacunga. Along the eastern chain are the great
+cones of El Altar, rising to an elevation of 16,383
+feet above the ocean, and having an enormous crater
+apparently dormant or extinct, and covered with snow;
+<span class="pagenum"><a name="Page_26" id="Page_26">[Pg 26]</a></span>then Cotopaxi (<a href="#FIGURE_2">Fig. 2</a>), its sides covered with snow,
+and sending forth from its crater several columns of
+smoke; then Guamani and Cayambe (19,000 feet), huge
+truncated cones apparently extinct; these constitute
+the eastern chain of volcanic heights. The western
+chain contains even loftier mountains. Here we find
+the gigantic Chimborazo, an extinct volcano whose
+summit is white with snow; Carihuairazo<a name="FNanchor_6_25" id="FNanchor_6_25"></a><a href="#Footnote_6_25" class="fnanchor">[6]</a> and Illiniza,
+a lofty pointed peak like the Matterhorn; Corazon, a
+snow-clad dome, reaching a height of 15,871 feet;
+Atacazo and Pichincha, the latter an extinct volcano
+reaching an elevation of 15,920 feet; such is the
+western chain, remarkable for its straightness, the
+volcanic cones being planted in one grand procession
+from south to north. This rectilinear arrangement of
+the western chain, only a little less conspicuous in the
+eastern, is very suggestive of a line of fracture
+in the crust beneath. And when we contemplate
+the prodigious quantity of matter included
+within the limits of these colossal domes and their
+environments, all of which has been extruded from the
+internal reservoirs, we gain some idea of the manner
+in which the contracting crust disposes of the matter
+it can no longer contain.<a name="FNanchor_7_26" id="FNanchor_7_26"></a><a href="#Footnote_7_26" class="fnanchor">[7]</a></p>
+
+<p>Between the volcanoes of Quito and those of Peru
+there is an intervening space of fourteen degrees of
+<span class="pagenum"><a name="Page_27" id="Page_27">[Pg 27]</a></span>latitude. This is occupied by the Andes, regarding
+the structure of which we have not much information
+except that at this part of its course it is not volcanic.
+But from Arequipa in Peru (lat. 16° S.), an active
+volcano, we find a new series of volcanic mountains
+continued southwards through Tacora (19,740 feet),
+then further south the more or less active vents of
+Sajama (22,915 feet), Coquina, Tutupaca, Calama,
+Atacama, Toconado, and others, forming an almost
+continuous range with that part of the desert of
+Atacama pertaining to Chili. Through this country
+we find the volcanic range appearing at intervals;
+and still more to the southwards it is doubtless connected
+with the volcanoes of Patagonia, north of the
+Magellan Straits, and of Tierra del Fuego. Mr.
+David Forbes considers that this great range of
+volcanic mountains, lying nearly north and south,
+corresponds to a line of fracture lying somewhat to
+the east of the range.<a name="FNanchor_8_27" id="FNanchor_8_27"></a><a href="#Footnote_8_27" class="fnanchor">[8]</a></p>
+
+<p>(<i>d.</i>) <i>Other Volcanic Chains.</i>&mdash;A similar statement in
+all probability applies to the systems of volcanic mountains
+of the Aleutian Isles, Kamtschatka, the Kuriles,
+the Philippines, and Sunda Isles. Nor can it be
+reasonably doubted that the western American coast-line
+has to a great extent been determined, or marked
+out, by such lines of displacement; for, as Darwin
+has shown, the whole western coast of South America,
+for a distance of between 2000 and 3000 miles south
+<span class="pagenum"><a name="Page_28" id="Page_28">[Pg 28]</a></span>of the Equator, has undergone an upward movement
+in very recent times&mdash;that is, within the period of
+living marine shells&mdash;during which period the volcanoes
+have been in activity.<a name="FNanchor_9_28" id="FNanchor_9_28"></a><a href="#Footnote_9_28" class="fnanchor">[9]</a></p>
+
+<p>(<i>e.</i>) <i>The Kurile Islands.</i>&mdash;This chain may also be
+cited in evidence of volcanic action along fissure lines.
+It connects the volcanoes of Kamtschatka with those
+of Japan, and the linear arrangement is apparent. In
+the former peninsula Erman counted no fewer than
+thirteen active volcanic mountains rising to heights
+of 12,000 to 15,000 feet above the sea.<a name="FNanchor_10_29" id="FNanchor_10_29"></a><a href="#Footnote_10_29" class="fnanchor">[10]</a> In the chain
+of the Kuriles Professor John Milne counted fifty-two
+well-defined volcanoes, of which nine, perhaps more,
+are certainly active.<a name="FNanchor_11_30" id="FNanchor_11_30"></a><a href="#Footnote_11_30" class="fnanchor">[11]</a> They are not so high as those
+of Kamtschatka; but, on the other hand, they rise
+from very deep oceanic waters, and have been
+probably built up from the sea bottom by successive
+eruptions of tuff, lava, and ash. According to the
+view of Professor Milne, the volcanoes of the Kurile
+chain are fast becoming extinct.</p>
+
+<p>(<i>f.</i>) <i>Volcanic Groups.</i>&mdash;Besides the volcanic vents
+arranged in lines, of which we have treated above,
+there are a large number, both active and extinct,
+which appear to be disposed in groups, or sporadically
+distributed, over various portions of the earth's surface.
+I say <i>appear to be</i>, because this sporadic
+distribution may really be resolvable (at least in
+some cases) into linear distribution for short distances.
+Thus the Neapolitan Group, which might
+<span class="pagenum"><a name="Page_29" id="Page_29">[Pg 29]</a></span>at first sight seem to be arranged round Vesuvius as
+a centre, really resolves itself into a line of active and
+extinct vents of eruption, ranging across Italy from
+the Tyrrhenian Sea to the Adriatic, through Ischia,
+Procida, Monte Nuovo and the Phlegræan Fields,
+Vesuvius, and Mount Vultur.<a name="FNanchor_12_31" id="FNanchor_12_31"></a><a href="#Footnote_12_31" class="fnanchor">[12]</a> Again, the extinct
+volcanoes of Central France, which appear to form
+an isolated group, indicate, when viewed in detail,
+a linear arrangement ranging from north to south.<a name="FNanchor_13_32" id="FNanchor_13_32"></a><a href="#Footnote_13_32" class="fnanchor">[13]</a>
+Another region over which extinct craters are distributed
+lies along the banks of the Rhine, above
+Bonn and the Moselle; a fourth in Hungary; a fifth
+in Asia Minor and Northern Palestine; and a sixth
+in Central Asia around Lake Balkash. These are
+all continental, and the linear distribution is not
+apparent.</p>
+
+<div class="footnote"><p><a name="Footnote_1_20" id="Footnote_1_20"></a><a href="#FNanchor_1_20"><span class="label">[1]</span></a> For an interesting account of this range of volcanic islands see
+Kingsley's <i>At Last</i>. The grandest volcanic peak is that of Guadeloupe,
+rising to a height of 5000 feet above the ocean, amidst a group
+of fourteen extinct craters. But the most active vent of the range is
+the Souffrière of St. Vincent. In the eruption of 1812 this mountain
+sent forth clouds of pumice, scoriæ and ashes, some of which were
+carried by an upper counter current to Barbados, one hundred miles to
+the eastward, covering the surface with volcanic dust to a depth of
+several inches.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_21" id="Footnote_2_21"></a><a href="#FNanchor_2_21"><span class="label">[2]</span></a> An excellent, and perhaps the most recent, map of this kind is that
+given by Professor Prestwich in his <i>Geology</i>, vol. i. p. 216. One on a
+larger scale is that by Keith Johnston in his <i>Physical Atlas</i>.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_22" id="Footnote_3_22"></a><a href="#FNanchor_3_22"><span class="label">[3]</span></a> <i>Memoir on the Physical Geology and Geography of Arabia Petræa,
+Palestine</i>, etc., published for the Committee of the Palestine Exploration
+Fund (1886), p. 113, etc.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_23" id="Footnote_4_23"></a><a href="#FNanchor_4_23"><span class="label">[4]</span></a> This mountain was ascended in 1837 by Mr. Taylor Thomson, who
+found the summit covered with sulphur, and from a cone fumes at a
+high temperature issued forth, but there was no eruption.&mdash;<i>Journ. Roy.
+Geographical Soc.</i>, vol. viii. p. 109.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_24" id="Footnote_5_24"></a><a href="#FNanchor_5_24"><span class="label">[5]</span></a> Humboldt, <i>Atlas der Kleineren Schriften</i> (1853).</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_25" id="Footnote_6_25"></a><a href="#FNanchor_6_25"><span class="label">[6]</span></a> Ascended by Whymper June 29, 1880. He found the elevation to
+be 16,515 feet.</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_26" id="Footnote_7_26"></a><a href="#FNanchor_7_26"><span class="label">[7]</span></a> The arrangement of the volcanoes of Peru and Bolivia is also suggestive
+of a double line of fissure, while those of Chili suggest one
+single line. The volcanoes of Arequipa, in the southern part of Peru,
+are dealt with by Dr. F. H. Hatch, in his inaugural dissertation,
+<i>Ueber die Gesteine der Vulcan-Gruppe von Arequipa</i> (Wien, 1886).
+The volcanoes rise to great elevations, having their summits capped by
+snow. The volcano of Charchani, lying to the north of Arequipa,
+reaches an elevation of 18,382 Parisian feet. That of Pichupichu
+reaches a height of 17,355 Par. feet. The central cone of Misti has
+been variously estimated to range from 17,240 to 19,000 Par. feet.
+The rocks of which the mountains are composed consist of varieties of
+andesite.</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_27" id="Footnote_8_27"></a><a href="#FNanchor_8_27"><span class="label">[8]</span></a> D. Forbes, "On the Geology of Bolivia and Southern Peru,"
+<i>Quarterly Journal of the Geological Society</i>, vol. xvii. p. 22 (1861).</p></div>
+
+<div class="footnote"><p><a name="Footnote_9_28" id="Footnote_9_28"></a><a href="#FNanchor_9_28"><span class="label">[9]</span></a> Darwin, <i>Structure and Distribution of Coral Reefs</i>, second edition,
+p. 186.</p></div>
+
+<div class="footnote"><p><a name="Footnote_10_29" id="Footnote_10_29"></a><a href="#FNanchor_10_29"><span class="label">[10]</span></a> Erman, <i>Reise um die Welt</i>.</p></div>
+
+<div class="footnote"><p><a name="Footnote_11_30" id="Footnote_11_30"></a><a href="#FNanchor_11_30"><span class="label">[11]</span></a> Milne, "Cruise amongst the Kurile Islands," <i>Geol. Mag.</i>, New
+Ser. (August 1879).</p></div>
+
+<div class="footnote"><p><a name="Footnote_12_31" id="Footnote_12_31"></a><a href="#FNanchor_12_31"><span class="label">[12]</span></a> See Daubeny, <i>Volcanoes</i>, Map I.</p></div>
+
+<div class="footnote"><p><a name="Footnote_13_32" id="Footnote_13_32"></a><a href="#FNanchor_13_32"><span class="label">[13]</span></a> Sir A. Geikie has connected as a line of volcanic vents those of
+Sicily, Italy, Central France, the N. E. of Ireland, the Inner Hebrides
+and Iceland, of which the central vents are extinct or dormant, the
+extremities active.</p></div>
+<p><span class="pagenum"><a name="Page_30" id="Page_30">[Pg 30]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_I_CHAPTER_IV" id="PART_I_CHAPTER_IV"></a>CHAPTER IV.
+<br /><br />
+MID-OCEAN VOLCANIC ISLANDS.</h2>
+
+
+<p><i>Oceanic Islands.</i>&mdash;By far the most extensive regions
+with sporadically distributed volcanic vents, both
+active and extinct, are those which are overspread
+by the waters of the ocean, where the vents emerge
+in the form of islands. These are to be found
+in all the great oceans, the Atlantic, the Pacific, and
+the Indian; but are especially numerous over the
+central Pacific region. As Kotzebue and subsequently
+Darwin have pointed out, all the islands of
+the Pacific are either coral-reefs or of volcanic origin;
+and many of these rise from great depths; that is to
+say, from depths of 1000 to 2000 fathoms. It is
+unnecessary here to attempt to enumerate all these
+islands which rise in solitary grandeur from the surface
+of the ocean, and are the scenes of volcanic operations;
+a few may, however, be enumerated.</p>
+
+<p><span class="pagenum"><a name="Page_31" id="Page_31">[Pg 31]</a></span></p>
+
+<div class="figcenter">
+<a name="FIGURE_4">
+  <img src="images/figure4.jpg" alt="Teneriffe from ocean" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 4.</span>&mdash;The Peak of Teneriffe (Pic de Teyde) as seen from the ocean.&mdash;(From a photograph.)
+</td></tr>
+</table>
+</div>
+
+<p>(<i>a.</i>) <i>Iceland.</i>&mdash;In the Atlantic, Iceland first claims
+notice, owing to the magnitude and number of its
+active vents and the variety of the accompanying
+phenomena, especially the geysers. As Lyell has
+observed,<a name="FNanchor_1_33" id="FNanchor_1_33"></a><a href="#Footnote_1_33" class="fnanchor">[1]</a> with the exception of Etna and Vesuvius,
+the most complete chronological records of a series of
+<span class="pagenum"><a name="Page_32" id="Page_32">[Pg 32]</a></span>eruptions in existence are those of Iceland, which
+come down from the ninth century of our era, and
+which go to show that since the twelfth century there
+has never been an interval of more than forty years
+without either an eruption or a great earthquake.
+So intense is the volcanic energy in this island that
+some of the eruptions of Hecla have lasted six years
+without cessation. Earthquakes have often shaken
+the whole island at once, causing great changes in
+the interior, such as the sinking down of hills, the
+rending of mountains, the desertion by rivers of their
+channels, and the appearance of new lakes. New
+islands have often been thrown up near the coast,
+while others have disappeared. In the intervals
+between the eruptions, innumerable hot springs
+afford vent to the subterranean heat, and solfataras
+discharge copious streams of inflammable
+matter. The volcanoes in different parts of the
+island are observed, like those of the Phlegræan
+Fields, to be in activity by turns, one vent serving for
+a time as a safety-valve for the others. The most
+memorable eruption of recent years was that of
+Skaptár Jokul in 1783, when a new island was thrown
+up, and two torrents of lava issued forth, one 45 and
+the other 50 miles in length, and which, according to
+the estimate of Professor Bischoff, contained matter
+surpassing in magnitude the bulk of Mont Blanc.
+One of these streams filled up a large lake, and,
+entering the channel of the Skaptâ, completely dried
+up the river. The volcanoes of Iceland may be considered
+as safety-valves to the region in which lie the
+British Isles.</p>
+
+<p>(<i>b.</i>) <i>The Azores, Canary, and Cape de Verde Groups.</i>&mdash;This
+group of volcanic isles rises from deep Atlantic
+<span class="pagenum"><a name="Page_33" id="Page_33">[Pg 33]</a></span>waters north of the Equator, and the vents of eruption
+are partially active, partially dormant, or extinct. It
+must be supposed, however, that at a former period
+volcanic action was vastly more energetic than at
+present; for, except at the Grand Canary, Gomera,
+Forta Ventura, and Lancerote, where various non-volcanic
+rocks are found, these islands appear to have
+been built up from their foundations of eruptive
+materials. The highest point in the Azores is the
+Peak of Pico, which rises to a height of 7016 feet
+above the ocean. But this great elevation is surpassed
+by that of the Peak of Teneriffe (or Pic de
+Teyde) in the Canaries, which attains to an elevation
+of 12,225 feet, as determined by Professor Piazzi
+Smyth.<a name="FNanchor_2_34" id="FNanchor_2_34"></a><a href="#Footnote_2_34" class="fnanchor">[2]</a></p>
+
+<p>This great volcanic cone, rising from the ocean,
+its summit shrouded in snow, and often protruding
+above the clouds, must be an object of uncommon
+beauty and interest when seen from the deck of a
+ship. (<a href="#FIGURE_4">Fig. 4</a>.) The central cone, formed of trachyte,
+pumice, obsidian, and ashes, rises out of a vast caldron
+of older basaltic rocks with precipitous inner walls&mdash;much
+as the cone of Vesuvius rises from within the
+partially encircling walls of Somma. (<a href="#FIGURE_5">Fig. 5</a>.) From
+the summit issue forth sulphurous vapours, but no
+flame.</p>
+
+<p>Piazzi Smyth, who during a prolonged visit to this
+mountain in 1856 made a careful survey of its form
+and structure, shows that the great cone is surrounded
+by an outer ring of basalt enclosing two <i>foci</i> of eruption,
+<span class="pagenum"><a name="Page_34" id="Page_34">[Pg 34]</a></span>the lavas from which have broken through the ring
+of the outer crater on the western side, and have
+poured down the mountain. At the top of the peak
+its once active crater is filled up, and we find a
+convex surface ("The Plain of Rambleta") surmounted
+towards its eastern end by a diminutive
+cone, 500 feet high, called "Humboldt's Ash Cone."
+The slope of the great cone of Teneriffe ranges from
+28° to 38°; and below a level of 7000 feet the general
+slope of the whole mountain down to the water's edge
+varies from 10° to 12° from the horizontal. The great
+cone is penetrated by numerous basaltic dykes.</p>
+
+<p>The Cape de Verde Islands, which contain beds of
+limestone along with volcanic matter, possess in the
+island of Fuego an active volcano, rising to a height
+of 7000 feet above the surface of the ocean. The
+central cone, like that of Teneriffe, rises from within
+an outer crater, formed of basalt alternating with beds
+of agglomerate, and traversed by numerous dykes of
+lava. This has been broken down on one side like
+that of Somma; and over its flanks are scattered
+numerous cones of scoriæ, the most recent dating
+from the years 1785 and 1799.<a name="FNanchor_3_35" id="FNanchor_3_35"></a><a href="#Footnote_3_35" class="fnanchor">[3]</a></p>
+
+<p><span class="pagenum"><a name="Page_35" id="Page_35">[Pg 35]</a></span></p>
+
+<div class="figcenter">
+<a name="FIGURE_5">
+  <img src="images/figure5.jpg" alt="Summit of Teneriffe" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 5.</span>&mdash;View of the summit of the Peak of Teneriffe (12,225 feet) and of the secondary crater, or outer ring
+of basaltic sheets which surrounds its base; seen from the east.&mdash;(After Leopold von Buch.)
+</td></tr>
+</table>
+</div>
+
+<p>The volcanoes of Lancerote have a remarkably
+linear arrangement from west to east across the
+island. They are not yet extinct; for an eruption
+in 1730 destroyed a large number of villages, and
+covered with lava the most fertile tracts in the island,
+which at the time of Leopold von Buch's visit lay
+waste and destitute of herbage.<a name="FNanchor_4_36" id="FNanchor_4_36"></a><a href="#Footnote_4_36" class="fnanchor">[4]</a> In the island of
+Palma there is one large central crater, the Caldera
+de Palma, three leagues in diameter, the walls of
+<span class="pagenum"><a name="Page_36" id="Page_36">[Pg 36]</a></span>which conform closely to the margin of the coast.
+Von Buch calls this crater "une merveille de la
+nature," for it distinguishes this isle from all the
+others, and renders it one of the most interesting and
+remarkable amongst the volcanic islands of the ocean.
+The outer walls are formed of basaltic sheets, and
+towards the south this great natural theatre is connected
+with the ocean by a long straight valley,
+called the "Barranco de los Dolores," along whose
+sides the structure of the mountain is deeply laid
+open to view. The outer flanks of the crater are
+furrowed by a great number of smaller barrancos
+radiating outward from the rim of the caldera. Von
+Buch regards the barrancos as having been formed
+during the upheaval of the island, according to his
+theory of the formation of such mountains (the elevation-theory);
+but unfortunately for his views, these
+ravines widen outwards from the centre, or at least do
+not become narrower in that direction, as would be
+the case were the elevation-theory sound. The maps
+which accompany Von Buch's work are remarkably
+good, and were partly constructed by himself.</p>
+
+<p>(<i>c.</i>) <i>Volcanic Islands in the Atlantic south of the
+Equator.</i>&mdash;The island of Ascension, formed entirely of
+volcanic matter, rises from a depth of 2000 fathoms
+in the very centre of the Atlantic. As described by
+Darwin, the central and more elevated portions are
+formed of trachytic matter, with obsidian and laminated
+ash beds. Amongst these are found ejected
+masses of unchanged granite, fragments of which
+have been torn from the central pipe during
+periods of activity, and would seem to indicate a
+granitic floor, or at least an original floor upon which
+more recent deposits may have been superimposed.
+<span class="pagenum"><a name="Page_37" id="Page_37">[Pg 37]</a></span>In St. Helena we seem, according to Daubeny, to
+have the mere wreck of one great crater, no one
+stream of lava being traceable to its source, while
+dykes of lava are scattered in profusion throughout
+the whole substance of the basaltic masses which
+compose the island. Tristan da Cunha, in the centre
+of the South Atlantic, rises abruptly from a depth of
+12,150 feet, at a distance of 1500 miles from any
+land; and one of its summits reaches an elevation
+of 7000 feet, being a truncated cone composed of
+alternating strata of tuff and augitic lava, surrounding
+a crater in which is a lake of pure water. The
+volcano is extinct or dormant.</p>
+
+<p>Were the waters of the ocean to be drawn off,
+these volcanic islands would appear like stupendous
+conical mountains, far loftier, and with sides more
+precipitous, than any to be found on our continental
+lands, all of which rise from platforms of considerable
+elevation. The enormous pressure of the water
+on their sides enables these mid-oceanic islands to
+stand with slopes varying from the perpendicular
+to a smaller extent than if they were sub-aerial;
+and it is on this account that we find them rising
+with such extraordinary abruptness from the "vasty
+deep."</p>
+
+<p>(<i>d.</i>) <i>Volcanic Islands of the Pacific.</i>&mdash;The volcanic
+islands of this great ocean are scattered over a wide
+tract on both sides of the equator. Those to the
+north of this line include the Sandwich Islands,
+the Mariana or Ladrone Islands, South Island, and
+Bonin Sima; south of the equator, the Galapagos,
+New Britain, Salomon, Santa Cruz, New Hebrides,
+the Friendly and Society Isles. While the coral
+reefs and islands of the Pacific may be recognised
+<span class="pagenum"><a name="Page_38" id="Page_38">[Pg 38]</a></span>by their slight elevation above the surface of the
+waters, those of volcanic origin and containing active
+or extinct craters of eruption generally rise into
+lofty elevations, so that the two kinds are called
+the <i>Low</i> Islands and <i>High</i> Islands respectively.
+Amongst the group are trachytic domes such as
+the Mountain of Tobreonu in the Society Islands,
+rising to a height probably not inferior to that of
+Etna, with extremely steep sides, and holding a
+lake on its summit.<a name="FNanchor_5_37" id="FNanchor_5_37"></a><a href="#Footnote_5_37" class="fnanchor">[5]</a> The linear arrangement of some
+of the volcanic islands of the Pacific is illustrated
+by those of the Tonga, or Friendly, Group, lying to
+the north of New Zealand. They consist of three
+divisions&mdash;(1) the volcanic; (2) those formed of
+stratified volcanic tuff, sometimes entirely or partially
+covered by coralline limestone; and (3) those which
+are purely coralline. The first form a chain of lofty
+cones and craters, lying in a E.N.E. and W.S.W.
+direction, and rising from depths of over 1000
+fathoms. Mr. J. J. Lister, who has described the
+physical characters of these islands, has shown very
+clearly that they lie along a line&mdash;probably that of a
+great fissure&mdash;stretching from the volcanic island of
+Amargura on the north (lat. 18° S.), through Lette,
+Metis, Kao (3030 feet), Tofua, Falcon, Honga Tonga,
+and the Kermadec Group into the New Zealand
+chain on the south. Some of these volcanoes are in
+a state of intermittent activity, as in the case of
+Tofua (lat. 20° 30' S.), Metis Island, and Amargura;
+the others are dormant or extinct. The whole
+group appears to have been elevated at a recent
+period, as some of the beds of coral have been
+raised 1272 feet and upward above the sea-level,
+<span class="pagenum"><a name="Page_39" id="Page_39">[Pg 39]</a></span>as in the case of Eua Island.<a name="FNanchor_6_38" id="FNanchor_6_38"></a><a href="#Footnote_6_38" class="fnanchor">[6]</a> The greater number
+of the Pacific volcanoes appear to be basaltic;
+such as those of the Hawaiian Group, which have
+been so fully described by Professor J. D. Dana.<a name="FNanchor_7_39" id="FNanchor_7_39"></a><a href="#Footnote_7_39" class="fnanchor">[7]</a>
+Here fifteen volcanoes of the first class have been
+in brilliant action; all of which, except three, are
+now extinct, and these are in Hawaii the largest
+and most eastern of the group. This island contains
+five volcanic mountains, of which Kea, 13,805
+feet, is the highest; next to that, Loa, 13,675 feet;
+after these, Hualalai, rising 8273 feet; Kilauea,
+4158 feet; and Kohala, 5505 feet above the sea; this
+last is largely buried beneath the lavas of Mauna Kea.
+The group contains a double line of volcanoes, one
+lying to the north and west of the other; and as the
+highest of the Hawaiian Group rises from a depth in
+the ocean of over 2000 fathoms, the total elevation
+of this mountain from its base on the bed of the
+ocean is not far from 26,000 feet, an elevation about
+that of the Himalayas. Mauna Kea has long been
+extinct, Hualalai has been dormant since 1801; but
+Mauna Loa is terribly active, there having been
+several eruptions, accompanied by earthquakes, within
+recent years, the most memorable being those of
+1852 and 1868. In the former case the lava rose
+from the deep crater into "a lofty mountain," as
+described by Mr. Coan,<a name="FNanchor_8_40" id="FNanchor_8_40"></a><a href="#Footnote_8_40" class="fnanchor">[8]</a> and then flowed away eastward
+for a distance of twenty miles. The interior of
+<span class="pagenum"><a name="Page_40" id="Page_40">[Pg 40]</a></span>the crater consists of a vast caldron, surrounded by a
+precipice 200 to 400 feet in depth, with a circumference
+of about fifteen miles, and containing within
+it a second crater, bounded by a black ledge with a
+steep wall of basalt&mdash;a crater within a crater; and from
+the floor of the inner crater, formed of molten basalt,
+in a seething and boiling state, arise a large number
+of small cones and pyramids of lava, some emitting
+columns of grey smoke, others brilliant flames and
+streams of molten lava, presenting a wonderful spectacle,
+the effect of which is heightened by the constant
+roaring of the vast furnaces below.<a name="FNanchor_9_41" id="FNanchor_9_41"></a><a href="#Footnote_9_41" class="fnanchor">[9]</a></p>
+
+<div class="footnote"><p><a name="Footnote_1_33" id="Footnote_1_33"></a><a href="#FNanchor_1_33"><span class="label">[1]</span></a> <i>Principles of Geology</i>, 11th edition, vol. ii. p. 48.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_34" id="Footnote_2_34"></a><a href="#FNanchor_2_34"><span class="label">[2]</span></a> Smyth, <i>Report on the Teneriffe Astronomical Experiment of 1856</i>.
+Humboldt makes the elevation 12,090 feet. A beautiful model of the
+Peak was constructed by Mr. J. Nasmyth from Piazzi Smyth's plans,
+of which photographs are given by the latter.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_35" id="Footnote_3_35"></a><a href="#FNanchor_3_35"><span class="label">[3]</span></a> Daubeny, <i>loc. cit.</i>, p. 460.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_36" id="Footnote_4_36"></a><a href="#FNanchor_4_36"><span class="label">[4]</span></a> <i>Iles Canaries</i>, p. 37.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_37" id="Footnote_5_37"></a><a href="#FNanchor_5_37"><span class="label">[5]</span></a> Daubeny, <i>loc. cit.</i>, p. 426.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_38" id="Footnote_6_38"></a><a href="#FNanchor_6_38"><span class="label">[6]</span></a> Lister, "Notes on the Geology of the Tonga Islands," <i>Quart.
+Jour. Geol. Soc.</i>, No. 188, p. 590 (1891).</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_39" id="Footnote_7_39"></a><a href="#FNanchor_7_39"><span class="label">[7]</span></a> Dana, <i>Characteristics of Volcanoes, with Contributions of Facts
+and Principles from the Hawaiian Islands</i>. London, 1890.&mdash;Also,
+<i>Geology of the American Exploring Expedition&mdash;Volcanoes of the
+Sandwich Islands</i>.</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_40" id="Footnote_8_40"></a><a href="#FNanchor_8_40"><span class="label">[8]</span></a> Coan, <i>Amer. Jour. of Science</i>, 1853.</p></div>
+
+<div class="footnote"><p><a name="Footnote_9_41" id="Footnote_9_41"></a><a href="#FNanchor_9_41"><span class="label">[9]</span></a> W. Ellis, the missionary, has given a vivid description of this
+volcano in his <i>Tour of Hawaii</i>. London, 1826.&mdash;Plans of the crater
+will be found in Professor Dana's work above quoted.</p></div>
+<p><span class="pagenum"><a name="Page_41" id="Page_41">[Pg 41]</a></span></p>
+
+
+<hr class="major" />
+<h1><a name="PART_II" id="PART_II"></a>PART II.
+<br /><br />
+EUROPEAN VOLCANOES.</h1>
+
+
+
+<hr class="major" />
+<h2><a name="PART_II_CHAPTER_I" id="PART_II_CHAPTER_I"></a>CHAPTER I.
+<br /><br />
+VESUVIUS.</h2>
+
+
+<p>Having now dealt in a necessarily cursory manner
+with volcanoes of distant parts of the globe, we may
+proceed to the consideration of the group of active
+volcanoes which still survive in Europe, as they possess
+a special interest, not only from their proximity and
+facility of access, at least to residents in Europe and
+the British Isles, but from their historic incidents;
+and in this respect Vesuvius, though not by any means
+the largest of the group, stands the first, and demands
+more special notice. The whole group rises from the
+shores of the Mediterranean, and consists of Vesuvius,
+Etna, Stromboli, one of the Lipari Islands, and
+Vulcano, a mountain which has given the name to all
+mountains of similar origin with itself.<a name="FNanchor_1_42" id="FNanchor_1_42"></a><a href="#Footnote_1_42" class="fnanchor">[1]</a> Along with
+these are innumerable cones and craters of extinct or
+dormant volcanoes, of which a large number have
+been thrown out on the flanks of Etna.</p>
+
+<p>(<i>a.</i>) <i>Prehistoric Ideas regarding the Nature of this
+Mountain.</i><span class="pagenum"><a name="Page_42" id="Page_42">[Pg 42]</a></span>&mdash;Down to the commencement of the
+Christian era this mountain had given no ostensible
+indication that it contained within itself a powerful
+focus of volcanic energy. True, that some vague
+tradition that the mountain once gave forth fire
+hovered around its borders; and several ancient
+writers, amongst them Diodorus Siculus and Strabo,
+inferred from the appearances of the higher parts of
+the mountain and the character of the rocks, which
+were "cindery and as if eaten by fire," that the
+country was once in a burning state, "being full of
+fiery abysses, though now extinct from want of fuel."
+Seneca (<span class="smcap">B.C.</span> 1 to <span class="smcap">A.D.</span> 64) had detected the true
+character of Vesuvius, as "having been a channel for
+the internal fire, but not its food;" nevertheless, at
+this period the flanks of the mountain were covered
+by fields and vineyards, while the summit, partially
+enclosed with precipitous walls of the long extinct
+volcano, Somma, was formed of slaggy and scoriaceous
+material, with probably a covering of scrub.
+Here it was that the gladiator Spartacus (<span class="smcap">B.C.</span> 72),
+stung by the intolerable evils of the Roman
+Government, retreated to the very summit of the
+mountain with some trusty followers. Clodius the
+Prætor, according to the narration of Plutarch, with
+a party of three thousand men, was sent against them,
+and besieged them in a mountain (meaning Vesuvius
+or Somma) having but one narrow and difficult
+passage, which Clodius kept guarded; all the rest
+was encompassed with broken and slippery precipices,
+but upon the top grew a great many wild vines;
+the besieged cut down as many as they had need of,
+and twisted them into ladders long enough to reach
+from thence to the bottom, by which, without any
+danger, all got down except one, who stayed behind
+to throw them their arms, after which he saved
+himself with the rest.<a name="FNanchor_2_43" id="FNanchor_2_43"></a><a href="#Footnote_2_43" class="fnanchor">[2]</a> "On the top" must (as
+Professor Phillips observes) be interpreted the summit
+of the exterior slope or crater edge, which would
+appear from the narrative to have broken down on
+one side, affording an entrance and mode of egress
+by which Spartacus fell upon, and surprised, the
+negligent Clodius Glabrus.</p>
+
+<p><span class="pagenum"><a name="Page_43" id="Page_43">[Pg 43]</a></span></p>
+
+<div class="figcenter">
+<a name="FIGURE_6">
+  <img src="images/figure6.jpg" alt="Vesuvius in 1 A.D." />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 6.</span>&mdash;Probable aspect of Vesuvius as it appeared at the beginning of the Christian era; seen from the Bay of Naples.
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_44" id="Page_44">[Pg 44]</a></span></p><p>In fancied security, villas, temples, and cities had
+been erected on the slopes of the mountain. Herculaneum,
+Pompeii, and Stabiæ, the abodes of art,
+luxury, and vice, had sprung up in happy ignorance
+that they "stood on a volcano," and that their prosperity
+was to have a sudden and disastrous close.<a name="FNanchor_3_44" id="FNanchor_3_44"></a><a href="#Footnote_3_44" class="fnanchor">[3]</a></p>
+
+<p>(<i>b.</i>) <i>Premonitory Earthquake Shocks.</i>&mdash;The first
+monitions of the impending catastrophe occurred in
+the 63rd year after Christ, when the whole Campagna
+was shaken by an earthquake, which did much damage
+to the towns and villas surrounding the mountain
+even beyond Naples. This was followed by other
+shocks; and in Pompeii the temple of Isis was so
+much damaged as to require reconstruction, which
+was undertaken and carried out by a citizen at his
+own expense.<a name="FNanchor_4_45" id="FNanchor_4_45"></a><a href="#Footnote_4_45" class="fnanchor">[4]</a> These earthquake shakings continued
+<span class="pagenum"><a name="Page_45" id="Page_45">[Pg 45]</a></span>for sixteen years. At length, on the night of August
+24th, <span class="smcap">A.D. 79</span>, they became so violent that the whole
+region seemed to reel and totter, and all things
+appeared to be threatened with destruction. The next
+day, about one in the afternoon, there was seen to
+rise in the direction of Vesuvius a dense cloud, which,
+after ascending from the summit of the mountain
+into the air for a certain height in one narrow, vertical
+trunk, spread itself out laterally in such a form that
+the upper part might be compared to the cluster of
+branches, and the lower to the stem of the pine which
+forms so common a feature in the Italian landscape.<a name="FNanchor_5_46" id="FNanchor_5_46"></a><a href="#Footnote_5_46" class="fnanchor">[5]</a></p>
+
+<p>(<i>c.</i>) <i>Pliny's Letters to Tacitus.</i>&mdash;For an account of
+what followed we are indebted to the admirable
+letters of the younger Pliny, addressed to
+the historian Tacitus, recounting the events which
+caused, or accompanied, the death of his uncle, the
+elder Pliny, who at the time of this first eruption of
+Vesuvius was in command of the Roman fleet at the
+entrance to the Bay of Naples. These letters, which
+are models of style and of accurate description, are too
+long to be inserted here; but he recounts how the
+dense cloud which hung over the mountain spread
+over the whole surrounding region, sometimes illuminated
+by flashes of light more vivid than lightning;
+how showers of cinders, stones, and ashes fell in
+such quantity that his uncle had to flee from Stabiæ,
+and that even at so great a distance as Misenum
+they encumbered the surface of the ground; how the
+ground heaved and the bed of the sea was upraised;
+how the cloud descended on Misenum, and even the
+island of Capreæ was concealed from view; and
+<span class="pagenum"><a name="Page_46" id="Page_46">[Pg 46]</a></span>finally, how, urged by a friend who had arrived from
+Spain, he, with filial affection, supported the steps of
+his mother in flying from the city of destruction.
+Such being the condition of the atmosphere and the
+effects of the eruption at a point so distant as Cape
+Misenum, some sixteen geographical miles from the
+focus of eruption, it is only to be expected that
+places not half the distance, such as Herculaneum,
+Pompeii, and even Stabiæ, with many villages and
+dwellings, should have shared a worse fate. The first
+of these cities, situated on the coast of the Bay of
+Naples, appears to have been overwhelmed by
+volcanic mud; Pompeii was buried in ashes and
+lapilli, and Stabiæ probably shared a similar fate.<a name="FNanchor_6_47" id="FNanchor_6_47"></a><a href="#Footnote_6_47" class="fnanchor">[6]</a></p>
+
+<p>(<i>d.</i>) <i>Appearance of the Mountain at the Commencement
+of the Christian Era.</i>&mdash;At the time of the first
+recorded eruption Vesuvius appears to have consisted
+of only a single cone with a crater, now known as
+<span class="pagenum"><a name="Page_47" id="Page_47">[Pg 47]</a></span>Monte di Somma, the central cone of eruption which
+now rises from within this outer ruptured casing not
+having been formed. (<a href="#FIGURE_6">Fig. 6</a>.) The first effect of the
+eruption of the year 79 was to blow out the solidified
+covering of slag and scoriæ forming the floor of the
+caldron. Doubtless at the close of the eruption a cone
+of fragmental matter and lava of some slight elevation
+was built up, and, if so, was subsequently destroyed;
+for, as we shall presently see by the testimony of the
+Abate Guilio Cesare Braccini, who examined the
+mountain not long before the great eruption of <span class="smcap">A.D.
+1631</span>, there was no central cone to the mountain at
+that time; and the mountain had assumed pretty
+much the appearance it had at the time that Spartacus
+took refuge within the walls of the great crater.</p>
+
+<p>(<i>e.</i>) <i>Destruction of Pompeii.</i>&mdash;Pompeii was overwhelmed
+with dry ashes and lapilli. Sir W. Hamilton
+found some of the stones to weigh eight pounds. At
+the time of the author's visit, early in April 1872, the
+excavations had laid open a section about ten feet
+deep, chiefly composed of alternating layers of small
+pumice stones (lapilli) and volcanic dust. It was
+during the sinking of a well in 1713 upon the theatre
+containing the statues of Hercules and Cleopatra that
+the existence of the ancient city was accidentally
+discovered.</p>
+
+<p>(<i>f.</i>) <i>More recent eruptions.</i>&mdash;Since the first recorded
+eruption in <span class="smcap">A.D. 79</span> down to the present day, Vesuvius
+has been the scene of numerous intermittent eruptions,
+of which some have been recorded; but many, doubtless,
+are forgotten.</p>
+
+<p>In <span class="smcap">A.D. 203</span>, during the reign of Severus, an eruption
+of extraordinary violence took place, which is
+related by Dion Cassius, from whose narrative we
+<span class="pagenum"><a name="Page_48" id="Page_48">[Pg 48]</a></span>may gather that at this time there was only one
+large crater, and that the central cone of Vesuvius
+had not as yet been upraised. In <span class="smcap">A.D. 472</span> an eruption
+occurred of such magnitude as to cover all Europe
+with fine dust, and spread alarm even at Constantinople.</p>
+
+<p>(<i>g.</i>) <i>Eruption of 1631.</i>&mdash;In December 1631 occurred
+the great convulsion whose memorials are written widely
+on the western face of Vesuvius in ruined villages. This
+eruption left layers of ashes over hundreds of miles of
+country, or heaps of mud swept down by hot water
+floods from the crater; the crater itself having been
+dissipated in the convulsion. Braccini, who examined
+the mountain not long before this eruption, found
+apparently no cone (or mount) like that of the modern
+Vesuvius. He states that the crater was five miles in
+circumference, about a thousand paces deep (or in
+sloping descent), and its sides covered with forest
+trees and brushwood, while at the bottom there was a
+plain on which cattle grazed.<a name="FNanchor_7_48" id="FNanchor_7_48"></a><a href="#Footnote_7_48" class="fnanchor">[7]</a> It would seem that
+the mountain had at this time enjoyed a long interval
+of rest, and that it had reverted to very much the
+same state in which it was at the period of the first
+eruption, when the flanks were peopled by inhabitants
+living in fancied security. But six months of violent
+earthquakes, which grew more violent towards the close
+of 1631, heralded the eruption which took place in
+December, accompanied by terrific noises from within
+the interior of the mountain. The inhabitants of the
+coast were thus warned of the approaching danger,
+and had several days to arrange for their safety; but
+in the end, a great part of Torre del Greco was
+destroyed, and a like fate overtook Resina and
+<span class="pagenum"><a name="Page_49" id="Page_49">[Pg 49]</a></span>Granatello, with a loss of life reported at 18,000
+persons. During the eruption clouds condensed into
+tempests of rain, and hot water from the mountain,
+forming deluges of mud, swept down the sides, and
+reached even to Nola and the Apennines. Nor was
+the sea unmoved. It retired during the violent earthquakes,
+and then returned full thirty paces beyond
+its former limits.</p>
+
+<p>Not indeed until near the close of the seventeenth
+century is there any evidence that the central cone of
+Vesuvius was in existence; but in October 1685 an
+eruption occurred which is recorded by Sorrentino,
+during which was erected "a new mountain within,
+and higher than the old one, and visible from Naples,"
+a statement evidently referable to the existing cone&mdash;so
+that it is little more than two centuries since this
+famous volcanic mountain assumed its present form.</p>
+
+<p>(<i>h.</i>) <i>Eruptions between the years 1500 and 1800.</i>&mdash;Since
+<span class="smcap">A.D. 1500</span> there have been fifty-six recorded
+eruptions of Vesuvius; one of these in 1767 was of
+terrific violence and destructiveness, and is represented
+by Sir William Hamilton in views taken both before
+and during the eruption. A pen-and-ink drawing of
+the appearance of the crater before the eruption is here
+reproduced from Hamilton's picture, from which it
+will be seen that the central crater contained within
+itself a second crater-cone, from whence steam, lava,
+and stones were being erupted (<a href="#FIGURE_7">Fig. 7</a>). Thus it will
+be seen that Vesuvius at this epoch consisted of three
+crater-cones within each other. The first, Monte di
+Somma; the second, the cone of Vesuvius; and the
+third, the little crater-cone within the second. During
+this eruption, vast lava-sheets invaded the fields and
+vineyards on the flanks of the mountain. A vivid
+<span class="pagenum"><a name="Page_50" id="Page_50">[Pg 50]</a></span>account of this eruption, as witnessed by Padre Torre,
+is given by Professor Phillips.<a name="FNanchor_8_49" id="FNanchor_8_49"></a><a href="#Footnote_8_49" class="fnanchor">[8]</a> We shall pass over
+others without further reference until we come down
+to our own times, in which Vesuvius has resumed its
+old character, and in one grand exhibition of volcanic
+energy, which took place in 1872, has evinced to the
+world that it still contains within its deep-seated
+laboratory all the elements of destructive force which
+it exhibited at the commencement of our era.</p>
+
+<div class="figcenter">
+<a name="FIGURE_7">
+  <img src="images/figure7.jpg" alt="Vesuvius before 1767" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 7.</span>&mdash;View of the crater of Vesuvius before the eruption of 1767,
+showing an interior crater-cone rising from the centre of the exterior
+crater.&mdash;(After Sir W. Hamilton.)
+</td></tr>
+</table>
+</div>
+
+<p>(<i>i.</i>) <i>Structure of the Neapolitan Campagna.</i>&mdash;But before
+giving a description of this terrific outburst of volcanic
+energy, it may be desirable to give some account
+of the physical position and structure of this mountain,
+by which the phenomena of the eruption will be better
+<span class="pagenum"><a name="Page_51" id="Page_51">[Pg 51]</a></span>understood. Vesuvius and the Neapolitan Campagna
+are formed of volcanic materials bounded on the west
+by the Gulf of Naples, and on the east and south by
+ranges of Jurassic limestone, a prolongation of the
+Apennines, which send out a spur bounding the bay on
+the south, and forming the promontory of Sorrento.
+The little island of Capri is also formed of limestone,
+and is dissevered from the promontory by a narrow
+channel. The northern side of the bay is, however,
+formed of volcanic materials; it includes the
+Phlegræan Fields (Campi Phlegræi), and terminates
+in the promontory of Miseno. Lying in the same
+direction are the islands of Procida and Ischia, also
+volcanic. Hence it will be seen that the two horns
+of the bay are formed of entirely different materials,
+that of Miseno on the north being volcanic, that of
+Sorrento on the south being composed of Jurassic
+limestone, of an age vastly more ancient than the
+volcanic rocks on the opposite shore. (<a href="#FIGURE_8">Map, p. 52</a>.)</p>
+
+<p>The general composition of the Neapolitan
+Campagna, from which the mountain rises, has
+been revealed by means of the Artesian well sunk to
+a depth of about 500 metres (1640 feet) at the Royal
+Palace of Naples, and may be generalised as
+follows:&mdash;</p>
+<div class="center">
+<table border="0" cellpadding="4" cellspacing="0" style="width:90%;" summary="">
+<tr>
+<td align="left" valign="middle" style="width:40%;">(1)&nbsp;&nbsp;From surface to depth of 715 feet</td>
+<td align="left"><span style="font-size:200%;">{</span></td>
+<td align="left">Recent beds of volcanic tuff with marine shells, and containing fragments of trachytic lava, etc. (<i>Volcanic Beds</i>).</td>
+</tr>
+<tr>
+<td align="left" valign="middle">(2)&nbsp;&nbsp;From 715 to 1420</td>
+<td align="left"><span style="font-size:200%;">{</span></td>
+<td align="left">Bituminous sands and marls with marine shells of recent species(?) (<i>Pre-Volcanic Beds</i>).</td>
+</tr>
+<tr>
+<td align="left" valign="middle">(3)&nbsp;&nbsp;From 1420 to 1574</td>
+<td align="left"><span style="font-size:200%;">{</span></td>
+<td align="left"><span class="smcap">Eocene Beds.</span> Micaceous sandstone and marl (<i>Macigno</i>).</td>
+</tr>
+<tr>
+<td align="left" valign="middle">(4)&nbsp;&nbsp;From 1574 to bottom</td>
+<td align="left"><span style="font-size:200%;">{</span></td>
+<td align="left"><span class="smcap">Jurassic Beds.</span> Apennine Limestone.</td>
+</tr>
+</table>
+</div>
+<p><span class="pagenum"><a name="Page_52" id="Page_52">[Pg 52]</a></span></p>
+
+<div class="figcenter">
+<a name="FIGURE_8">
+  <img src="images/figure8.jpg" alt="Bay of Naples" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 8.</span>&mdash;Map of the district bordering the Bay of Naples, with the
+islands of Capri, Ischia, and Procida.
+</td></tr>
+</table>
+</div>
+
+<p>From the above section, for which we are indebted to
+Mr. Johnston-Lavis, the most recent writer on Vesuvius,
+it would appear that the first volcanic explosions by
+which the mountain was ultimately to be built up
+took place after the deposition of the sands and
+marls (No. 2), while the whole Campagna was submerged
+under the waters of the Mediterranean. By
+the accumulation of the stratified tuff (No. 1), the sea-bed
+was gradually filled up during a period of volcanic
+activity, and afterwards elevated into dry land.<a name="FNanchor_9_50" id="FNanchor_9_50"></a><a href="#Footnote_9_50" class="fnanchor">[9]</a></p>
+
+<p><span class="pagenum"><a name="Page_53" id="Page_53">[Pg 53]</a></span></p>
+
+<div class="figcenter">
+<a name="FIGURE_9">
+  <img src="images/figure9.jpg" alt="Vesuvius eruption of 1872" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 9.</span>&mdash;View of Vesuvius from the Harbour of Naples at the commencement of the eruption of 1872.&mdash;(From
+a sketch by the author.)
+</td></tr>
+</table>
+</div>
+
+<p>(<i>j.</i>) <i>Present Form and Structure of Vesuvius and
+Somma.</i>&mdash;The outer cone of Vesuvius, or Monte di
+Somma, rises from a circular platform by a moderately
+gentle ascent, and along the north and east terminates
+<span class="pagenum"><a name="Page_54" id="Page_54">[Pg 54]</a></span>in a craggy crest, with a precipitous cliff descending
+into the Atria del Cavallo, forming the wall of the
+ancient crater throughout half its circumference; this
+wall is formed of scoriæ, ashes, and lapilli, and is
+traversed by numerous dykes of lava. Along the
+west and south this old crater has been broken
+down; but near the centre there remains a round-backed
+ridge of similar materials, once doubtless a
+part of the original crater of Somma, rising above
+the slopes of lava on either hand. On this has been
+erected the Royal Observatory, under the superintendence
+of Professor Luigi Palmieri, where continuous
+observations are being made, by means of delicate
+seismometers, of the earth-tremors which precede or
+accompany eruptions; for it is only justice to say that
+Vesuvius gives fair warning of impending mischief,
+and the instruments are quick to notify any premonitory
+symptoms of a coming catastrophe. The elevation
+of the Observatory is 2080 feet above the sea.</p>
+
+<p>On either side of the Observatory ridge are wide
+channels filled to a certain height with lavas of the
+nineteenth and preceding centuries, the most recent
+presenting an aspect which can only be compared to
+a confused multitude of black serpents and pachyderms
+writhing and interlocked in some frightful
+death-struggle. Some of this lava, ten years old, as
+we cross its rugged and black surface presents gaping
+fissures, showing the mass to be red-hot a few feet
+from the surface, so slow is the process of cooling.
+These lava-streams&mdash;some of them reaching to the
+sea-coast&mdash;have issued forth from the Atria at
+successive periods of eruption.</p>
+
+<p>From the midst of the Atria rises the central
+cone, formed of cinders, scoriæ, and lava-streams, and
+<span class="pagenum"><a name="Page_55" id="Page_55">[Pg 55]</a></span>fissured along lines radiating from the axis. This
+cone is very steep, the angle being about 40°-45°
+from the horizontal, and is formed of loose cindery
+matter which gives way at every step, and is rather
+difficult to climb. But on reaching the summit we
+look down into the crater, displaying a scene of ever-varying
+characters, rather oval in form, and about
+1100 yards in diameter. From the map of Professor
+Guiscardi, published in 1855, there are seen two
+minor craters within the central one, formed in 1850,
+and an outflow of lava from the N.W. down the
+cone. At the time of the author's visit the crater
+was giving indications, by the great quantity of sulphurous
+gas and vapour rising from its surface, and
+small jets of molten lava beginning to flow down
+the outer side, of the grand outburst of internal
+forces which was presently to follow.</p>
+
+<p>(<i>k.</i>) <i>Eruption of 1872.</i>&mdash;The grand eruption of
+1872, of which a detailed account is given by Professor
+Palmieri,<a name="FNanchor_10_51" id="FNanchor_10_51"></a><a href="#Footnote_10_51" class="fnanchor">[10]</a> commenced with a slight discharge of incandescent
+projectiles from the crater; and on the
+13th January an aperture appeared on the upper edge
+of the cone from which at first a little lava issued
+forth, followed by the uprising of a cone which
+threw out projectiles accompanied by smoke, whilst
+the central crater continued to detonate more loudly
+and frequently. This little cone ultimately increased
+in size, until in April it filled the whole crater and
+rose four or five metres above the brim. At this
+time abundant lavas poured down from the base of
+the cone into the Atria del Cavallo, thence turned
+into the Fossa della Vetraria in the direction of the
+<span class="pagenum"><a name="Page_56" id="Page_56">[Pg 56]</a></span>Observatory and towards the Crocella, where they
+accumulated to such an extent as to cover the hillside
+for a distance of about 300 metres; then turning
+below the Canteroni, formed a hillock without spreading
+much farther.</p>
+
+<p>In October another small crater was formed by the
+falling in of the lava, which after a few days gave vent
+to smoke and several jets of lava; and towards the
+end of October the detonations increased, the smoke
+from the central crater issued forth more densely
+mixed with ashes, and the seismographical apparatus
+was much disturbed. On the 3rd and 4th November
+copious and splendid lava-streams coursed down the
+principal cone on its western side, but were soon
+exhausted; and in the beginning of 1872 the little
+cone, regaining vigour, began to discharge lava from
+the summit instead of the base as heretofore.</p>
+
+<p>In the month of March 1873, with the full moon,
+the cone opened on the north-west side&mdash;the cleavage
+being indicated by a line of fumaroles&mdash;and lava
+issued from the base and poured down into the Atria
+as far as the precipices of Monte di Somma. On the
+23rd April (another full moon) the activity of the
+craters increased, and on the evening of the 24th
+splendid lava-streams descended the cone in various
+directions, attracting on the same night the visits of
+a great many strangers. A lamentable event followed
+on the 26th. A party of visitors, accompanied by
+inexperienced guides, and contrary to the advice of
+Professor Palmieri, insisted on ascending to the place
+from which the lava issued. At half-past three on the
+morning of the 26th they were in the Atria del Cavallo,
+when the Vesuvian cone was rent in a north-west
+direction and a copious torrent of lava issued forth.
+<span class="pagenum"><a name="Page_57" id="Page_57">[Pg 57]</a></span>Two large craters formed at the summit of the
+mountain, discharging incandescent projectiles and
+ashes. A cloud of smoke enveloped the unhappy
+visitors, who were under a hail-storm of burning
+projectiles. Eight were buried beneath it, or in
+the lava, while eleven were grievously injured.<a name="FNanchor_11_52" id="FNanchor_11_52"></a><a href="#Footnote_11_52" class="fnanchor">[11]</a>
+The lava-stream, flowing over that of 1871 in the
+Atria, divided into two branches, the smaller one
+flowing towards Resina, but stopping before reaching
+the town; the larger precipitated itself into the Fossa
+della Vetraria, occupying the whole width of 800
+metres, and traversing the entire length of 1300
+metres in three hours. It dashed into the Fossa di
+Farone, and reached the villages of Massa and St.
+Sebastiano, covering a portion of the houses, and, continuing
+its course through an artificial foss, or trench,
+invaded cultivated ground and several villages. If it
+had not greatly slackened after midnight, from failure
+of supply at its source, it would have reached Naples
+by Ponticelli and flowed into the sea. The eruption
+towards the end of April had reached its height. The
+Observatory ridge was bounded on either side by two
+fiery streams, which rendered the heat intolerable.
+Simultaneously with the opening of the great fissure
+two large craters opened at the summit, discharging
+with a dreadful noise an immense cloud of smoke and
+ashes, with bombs which rose to a height of 1300
+metres above the brim of the volcano.<a name="FNanchor_12_53" id="FNanchor_12_53"></a><a href="#Footnote_12_53" class="fnanchor">[12]</a> The torrents
+of fire which threatened Resina, Bosco, and Torre
+Annunziata, and which devastated the fertile country
+<span class="pagenum"><a name="Page_58" id="Page_58">[Pg 58]</a></span>of Novelle, Massa, St. Sebastiano, and Cerole, and
+two partially buried cities, the continual thunderings
+and growling of the craters, caused such terror, that
+numbers abandoned their dwellings, flying for refuge
+into Naples, while many Neapolitans went to Rome
+or other places. Fortunately, the paroxysm had now
+passed, the lava-streams stopped in their course, and
+the great torrent which passed the shoulders of the
+Observatory through the Fossa della Vetraria lowered
+the level of its surface below that of its sides, which
+appeared like two parallel ramparts above it. Had
+these streams continued to flow on the 27th of April
+as they had done on the previous night, they would
+have reached the sea, bringing destruction to the very
+walls of Naples. During this eruption Torre del
+Greco was upraised to the extent of two metres, and
+nearly all the houses were knocked down.</p>
+
+<p>The igneous period of eruption having terminated,
+the ashes, lapilli, and projectiles became more
+abundant, accompanied by thunder and lightning.
+On the 28th they darkened the air, and the terrific
+noise of the mountain continuing or increasing, the
+terror at Resina, Portici, and Naples became universal.
+It seemed as though the tragic calamities
+of the eruption of <span class="smcap">A.D.</span> 79 were about to be repeated.
+But gradually the force of the explosions decreased,
+and the noise from the crater became discontinuous,
+so that on the 30th the detonations were very few,
+and by the 1st May the eruption was completely
+over.</p>
+
+<p>Such is a condensed account of one of the most
+formidable eruptions of our era. In the frontispiece
+of this volume a representation, taken (by permission)
+from a photograph by Negretti &amp; Zambra, is given,
+<span class="pagenum"><a name="Page_59" id="Page_59">[Pg 59]</a></span>showing the appearance of Vesuvius during the final
+stage of the eruption, when prodigious masses of
+smoke, steam, and illuminated gas issued forth from
+the summit and overspread the whole country around
+with a canopy which the light of the sun could
+scarcely penetrate.</p>
+
+<p>It will be noticed in the above account that, concurrently
+with the full moon, there were two distinct
+and special outbreaks of activity; one occurring in
+March, the other in the month following. That the
+conditions of lunar and solar attraction should have
+a marked effect on a part of the earth's crust, while
+under the tension of eruptive forces, is only what
+might be expected. At full moon the earth is
+between the sun and the moon, and at new moon
+the moon is between the sun and the earth;
+under these conditions (the two bodies acting in
+concert) we have spring tides in the ocean, and a
+maximum of attraction on the mass of the earth.
+Hence the crust, which at the time referred to was
+under tremendous strain, only required the addition
+of that caused by the lunar and solar attractions to
+produce rupture in both cases, giving rise to increased
+activity, and the extrusion of lava and volatile matter.
+It may, in general, be safely affirmed that low barometric
+pressure on the one hand, and the occurrence
+of the syzygies (when the attractions of the sun and
+moon are in the same line) on the other, have had
+great influence in determining the crises of eruptions
+of volcanic mountains when in a state of unrest.</p>
+
+<p><i>Contrast between the Northern and Southern Slopes.</i>&mdash;Before
+leaving Vesuvius it may be observed that
+throughout all the eruptions of modern times the
+northern side of the mountain, that is the old crater
+<span class="pagenum"><a name="Page_60" id="Page_60">[Pg 60]</a></span>and flank of Somma, has been secure from the
+lava-flows, and has enjoyed an immunity which does
+not belong to the southern and western side. If we
+look at a map of the mountain showing the direction
+of the streams during the last three centuries,<a name="FNanchor_13_54" id="FNanchor_13_54"></a><a href="#Footnote_13_54" class="fnanchor">[13]</a> we
+observe that all the streams of that period flowed
+down on the side overlooking the Bay of Naples; on
+the opposite side the wall of Monte di Somma
+presents an unbroken front to the lava-streams. From
+this it may be inferred that one side, the west, is
+weaker than the other; and consequently, when the
+lava and vapours are being forced upwards, under
+enormous pressure from beneath, the western side
+gives way under the strain, as in the case of the
+fissure of 1872, and the lava and vapours find means
+of escape. From what has happened in the past it
+is clear that no place on the western side of the
+mountain is entirely safe from devastation by floods
+of lava; while the prevalent winds tend to carry the
+ashes and lapilli, which are hurled into the air, in the
+same westerly direction.</p>
+
+<div class="footnote"><p><a name="Footnote_1_42" id="Footnote_1_42"></a><a href="#FNanchor_1_42"><span class="label">[1]</span></a> For an excellent view of this remarkable volcanic group see Judd's
+<i>Volcanoes</i>, 4th edition, p. 43.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_43" id="Footnote_2_43"></a><a href="#FNanchor_2_43"><span class="label">[2]</span></a> Plutarch, <i>Life of Cassius</i>; <i>ed. Reiske</i>, vol. iii. p. 240.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_44" id="Footnote_3_44"></a><a href="#FNanchor_3_44"><span class="label">[3]</span></a> Strabo gives the following account of the appearance and condition
+of Vesuvius in his day:&mdash;"Supra hæc loca situs est Vesuvius mons,
+agris cinctus optimis; dempto vertice, qui magna sui parte planus,
+totus sterilis est, adspectu sinereus, cavernasque ostendens fistularum
+plenas et lapidum colore fuliginoso, utpote ab igni exesorum. Ut conjectarum
+facere possis, ista loca quondam arsisse et crateras ignis
+habuisse, deinde materia deficiente restricta fuisse."&mdash;<i>Rer. Geog.</i>, lib. v.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_45" id="Footnote_4_45"></a><a href="#FNanchor_4_45"><span class="label">[4]</span></a> A tablet over the entrance records this act of pious liberality, and
+is given by Phillips, <i>loc. cit.</i>, p. 12.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_46" id="Footnote_5_46"></a><a href="#FNanchor_5_46"><span class="label">[5]</span></a> The stone pine, <i>Pinus pinea</i>, which Turner knew how to use with
+so much effect in his Italian landscapes.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_47" id="Footnote_6_47"></a><a href="#FNanchor_6_47"><span class="label">[6]</span></a> Bulwer Lytton's <i>Last Days of Pompeii</i> presents to the reader a
+graphic picture of the terrible event here referred to:&mdash;"The eyes of the
+crowd followed the gesture of the Egyptian, and beheld with ineffable
+dismay a vast vapour shooting from the summit of Vesuvius, in the
+form of a gigantic pine tree; the trunk&mdash;blackness, the branches&mdash;fire!
+A fire that shifted and wavered in its hues with every moment&mdash;now
+fiercely luminous, now of a dull and dying red that again blazed
+terrifically forth with intolerable glare!... Then there arose on high
+the shrieks of women; the men stared at each other, but were speechless.
+At that moment they felt the earth shake beneath their feet;
+the walls of the theatre trembled; and beyond, in the distance, they
+heard the crash of falling roofs; an instant more and the mountain-cloud
+seemed to roll towards them, dark and rapid; at the same time
+it cast forth from its bosom a shower of ashes mixed with vast fragments
+of burning stone. Over the crushing vines&mdash;over the desolate streets&mdash;over
+the amphitheatre itself&mdash;far and wide, with many a mighty
+splash in the agitated sea, fell that awful shower." A visit to the disinterred
+city will probably produce on the mind a still more lasting and
+vivid impression of the swift destruction which overtook this city.</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_48" id="Footnote_7_48"></a><a href="#FNanchor_7_48"><span class="label">[7]</span></a> Quoted by Phillips, <i>loc. cit.</i>, p. 45.</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_49" id="Footnote_8_49"></a><a href="#FNanchor_8_49"><span class="label">[8]</span></a> <i>Vesuvius</i>, p. 72 <i>et seq.</i></p></div>
+
+<div class="footnote"><p><a name="Footnote_9_50" id="Footnote_9_50"></a><a href="#FNanchor_9_50"><span class="label">[9]</span></a> Johnston-Lavis, "On the Geology of Monti Somma and Vesuvius,"
+<i>Quart. Jour. Geol. Soc.</i>, vol. 40 (1884).</p></div>
+
+<div class="footnote"><p><a name="Footnote_10_51" id="Footnote_10_51"></a><a href="#FNanchor_10_51"><span class="label">[10]</span></a> Palmieri, <i>Eruption of Vesuvius in 1872</i>, with notes, etc., by
+Robert Mallet, F.R.S. London, 1873.</p></div>
+
+<div class="footnote"><p><a name="Footnote_11_52" id="Footnote_11_52"></a><a href="#FNanchor_11_52"><span class="label">[11]</span></a> Those who lost their lives were medical students, and an Assistant
+Professor in the University, Antonio Giannone by name.</p></div>
+
+<div class="footnote"><p><a name="Footnote_12_53" id="Footnote_12_53"></a><a href="#FNanchor_12_53"><span class="label">[12]</span></a> Involving, as Mr. Mallet calculates, an initial velocity of projection
+of above 600 feet per second.</p></div>
+
+<div class="footnote"><p><a name="Footnote_13_54" id="Footnote_13_54"></a><a href="#FNanchor_13_54"><span class="label">[13]</span></a> Such as that given by Professor Phillips in his <i>Vesuvius</i>.</p></div>
+<p><span class="pagenum"><a name="Page_61" id="Page_61">[Pg 61]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_II_CHAPTER_II" id="PART_II_CHAPTER_II"></a>CHAPTER II.
+<br /><br />
+ETNA.</h2>
+
+
+<p>(<i>a.</i>) <i>Structure of the Mountain.</i>&mdash;Etna, unlike Vesuvius,
+has ever been a burning mountain; hence it
+was well known as such to classic writers before the
+Christian era. The structure and features of this
+magnificent mountain have been abundantly illustrated
+by Elie de Beaumont,<a name="FNanchor_1_55" id="FNanchor_1_55"></a><a href="#Footnote_1_55" class="fnanchor">[1]</a> Daubeny,<a name="FNanchor_2_56" id="FNanchor_2_56"></a><a href="#Footnote_2_56" class="fnanchor">[2]</a> Baron von
+Waltershausen,<a name="FNanchor_3_57" id="FNanchor_3_57"></a><a href="#Footnote_3_57" class="fnanchor">[3]</a> and Lyell,<a name="FNanchor_4_58" id="FNanchor_4_58"></a><a href="#Footnote_4_58" class="fnanchor">[4]</a> of whose writings I shall
+freely avail myself in the following account, not
+having had the advantage of a personal examination
+of this region.</p>
+
+<p><i>Structure of Etna.</i>&mdash;So large is Etna that it would
+enclose within its ample skirts several cones of the size
+of Vesuvius. It rises to a height of nearly 11,000
+feet above the waters of the Mediterranean,<a name="FNanchor_5_59" id="FNanchor_5_59"></a><a href="#Footnote_5_59" class="fnanchor">[5]</a> and is
+planted on a floor consisting of stratified marine
+volcanic matter, with clays, sands, and limestones of
+newer Pliocene age. Its base is nearly circular, and
+has a circumference of 87 English miles. In ascending
+<span class="pagenum"><a name="Page_62" id="Page_62">[Pg 62]</a></span>its flanks we pass successively over three well-defined
+physical zones: the lowest, or fertile zone,
+comprising the tract around the skirts of the mountain
+up to a level of about 2500 feet, being well cultivated
+and covered by dwellings surrounded by olive groves,
+fields, vineyards, and fruit-trees; the second, or forest
+zone, extending to a level of about 6270 feet, clothed
+with chestnut, oak, beech, and cork trees, giving place
+to pines; and the third, extending to the summit and
+called "the desert region," a waste of black lava and
+scoriæ with mighty crags and precipices, terminating
+in a snow-clad tableland, from which rises the central
+cone, 1100 feet high, emitting continually steam and
+sulphurous vapours, and in the course of almost every
+century sending forth streams of molten lava.</p>
+
+<p>The forest zone is remarkable for the great number
+of minor craters which rise up from the midst of
+the foliage, and are themselves clothed with trees.
+Sartorius von Waltershausen has laid down on his
+map of Etna about 200 of these cones and craters,
+some of which, like those of Auvergne, have been
+broken down on one side. Many of these volcanoes of
+second or third magnitude lie outside the forest zone,
+both above and below it; such as the double hill of
+Monti Rossi, near Nicolosi, formed in 1659, which
+is 450 feet in height, and two miles in circumference
+at its base. Sir C. Lyell observes that
+these minor crater-cones present us with one of
+the most delightful and characteristic scenes in
+Europe. They occur of every variety of height and
+size, and are arranged in picturesque groups. However
+uniform they may appear when seen from
+the sea or the plains below, nothing can be more
+diversified than their shape when we look from above
+<span class="pagenum"><a name="Page_63" id="Page_63">[Pg 63]</a></span>into their ruptured craters. The cones situated in
+the higher parts of the forest zone are chiefly clothed
+with lofty pines; while those at a lower elevation are
+adorned with chestnuts, oaks, and beech trees. These
+cones have from time to time been buried amidst
+fresh lava-streams descending from the great crater,
+and thus often become obliterated.</p>
+
+<div class="figcenter">
+<a name="FIGURE_10">
+  <img src="images/figure10.jpg" alt="Section through Etna" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 10.</span>&mdash;Ideal Section through Etna. (After Lyell.)&mdash;A. Axis of
+present cone of eruption; B. Axis of extinct cone of eruption; <i>a.</i> Older
+lavas, chiefly trachytic; <i>b.</i> Newer lavas, erupted (with <i>a</i>) before origin
+of the Val del Bove; <i>c.</i> Scoria and lava of recent age; T. Tertiary
+strata forming the foundation to the volcanic rocks. The position of
+the Val del Bove before its formation is shown by the lightly-shaded
+portion above B.
+</td></tr>
+</table>
+</div>
+
+<p>(<i>b.</i>) <i>Val del Bove.</i>&mdash;The most wonderful feature of
+Mount Etna is the celebrated Val del Bove (Valle del
+Bue), of which S. von Waltershausen has furnished a
+very beautiful plate<a name="FNanchor_6_60" id="FNanchor_6_60"></a><a href="#Footnote_6_60" class="fnanchor">[6]</a>&mdash;a vast amphitheatre hewn
+out of the eastern flank of the mountain, just below
+the snow-mantled platform. It is a physical feature
+somewhat after the fashion of Monte Somma in
+Vesuvius, but exceeds it in magnitude as Etna
+exceeds Vesuvius. The Val del Bove is about five
+miles in diameter, bounded throughout three-fourths
+of its circumference by precipitous walls of ashes,
+scoriæ, and lava, traversed by innumerable dykes, and
+rising inwards to a height of between 3000 and 4000
+<span class="pagenum"><a name="Page_64" id="Page_64">[Pg 64]</a></span>feet. Towards the east the cliffs gradually fall to a
+height of about 500 feet, and at this side the vast
+chasm opens out upon the slope of the mountain. At
+the head of the Val del Bove rises the platform,
+surmounted by the great cone and crater. It will
+thus be seen that by means of this hollow we have
+access almost to the very heart of the mountain.</p>
+
+<p>What is very remarkable about the structure of this
+valley is that the beds exhibit "the <i>quâ-quâ</i> versal
+dip"&mdash;in other words, they dip away on all sides from
+the centre&mdash;which has led to the conclusion that in
+the centre is a focus of eruption which had become
+closed up antecedently to the formation of the valley
+itself. Lyell has explained this point very clearly by
+showing that this focus had ceased to eject matter at
+some distant period, and that the existing crater at
+the summit of the mountain had poured out its lavas
+over those of the extinct orifice. This was prior to
+the formation of the Val del Bove itself; and the
+question remains for consideration how this vast
+natural amphitheatre came to be hollowed out; for
+its structure shows unquestionably that it owes its
+form to some process of excavation.</p>
+
+<p>In the first place, it is certainly not the work of
+running water, as in the case of the cañons of
+Colorado; the porous matter of which the mountain
+is formed is quite incapable of originating and supporting
+a stream of sufficient volume to excavate and
+carry away such enormous masses of matter within
+the period required for the purpose. We must therefore
+have recourse to some other agency. Numerous
+illustrations are to be found of the explosive action of
+volcanoes in blowing off either the summits of mountains,
+or portions of their sides. For example, there
+<span class="pagenum"><a name="Page_65" id="Page_65">[Pg 65]</a></span>is reason for believing that the first result of the
+renewed energy of Vesuvius was to blow into the air
+the upper surface of the mountain. Again, so late as
+1822, during a violent earthquake in Java, a country
+which has been repeatedly devastated by earthquakes
+and volcanic eruptions, the mountain of Galongoon,
+which was covered by a dense forest, and situated in
+a fertile and thickly-peopled region, and had never
+within the period of tradition been in activity, was
+thus ruptured by internal forces. In the month of
+July 1822, after a terrible earthquake, an explosion
+was heard, and immense columns of boiling water,
+mixed with mud and stones, were projected from the
+mountain like a water-spout, and in falling filled up the
+valleys, and covered the country with a thick deposit
+for many miles, burying villages and their inhabitants.
+During a subsequent eruption great blocks of basalt
+were thrown to a distance of seven miles; the result
+of all being that an enormous semicircular gulf was
+formed between the summit and the plain, bounded
+by steep cliffs, and bearing considerable resemblance
+to the Val del Bove. Other examples of the power
+of volcanic explosions might be cited; but the above
+are sufficient to show that great hollows may thus be
+formed either on the summits or flanks of volcanic
+mountains. Chasms may also be formed by the
+falling in of the solidified crust, owing to the extrusion
+of molten matter from some neighbouring vent of
+eruption; and it is conceivable that by one or other
+of these processes the vast chasm of the Val del Bove
+on the flanks of Etna may have been produced.</p>
+
+<p>(<i>c.</i>) <i>The Physical History of Etna.</i>&mdash;The physical
+history of Etna seems to be somewhat as follows:&mdash;</p>
+
+<p><i>First Stage.</i>&mdash;Somewhere towards the close of the
+<span class="pagenum"><a name="Page_66" id="Page_66">[Pg 66]</a></span>Tertiary period&mdash;perhaps early Pliocene or late
+Miocene&mdash;a vent of eruption opened on the floor of
+the Mediterranean Sea, from which sheets of lava
+were poured forth, and ashes mingled with clays and
+sands, brought down from the neighbouring lands,
+were strewn over the sea-bed. During a pause in
+volcanic activity, beds of limestone with marine shells
+were deposited.</p>
+
+<p><i>Second Stage.</i>&mdash;This sea-bed was gradually upraised
+into the air, while fresh sheets of lava and other <i>ejecta</i>
+were accumulated round the vents of eruption, of
+which there were two principal ones&mdash;the older under
+the present Val del Bove, the newer under the summit
+of the principal cone. Thus was the mountain gradually
+piled up.</p>
+
+<p><i>Third Stage.</i>&mdash;The vent under the Val del Bove
+ceased to extrude more matter, and became extinct.
+Meanwhile the second vent continued active, and,
+piling up more and more matter round the central
+crater, surmounted the former vent, and covered its
+<i>ejecta</i> with newer sheets of lava, ashes, and lapilli,
+while numerous smaller vents, scattered all over the
+sides of the mountain, gave rise to smaller cones and
+craters.</p>
+
+<p><i>Fourth Stage.</i>&mdash;This stage is signalised by the
+formation of the Val del Bove through some grand
+explosion, or series of explosions, by which this vast
+chasm was opened in the side of the mountain, as
+already explained.</p>
+
+<p><i>Fifth Stage.</i>&mdash;This represents the present condition
+of the mountain, whose height above the sea is due,
+not only to accumulation of volcanic materials round
+the central cone, but to elevation of the whole island,
+as evinced by numerous raised beaches of gravel and
+<span class="pagenum"><a name="Page_67" id="Page_67">[Pg 67]</a></span>sand, containing shells and other forms of marine
+species now living in the waters of the Mediterranean.<a name="FNanchor_7_61" id="FNanchor_7_61"></a><a href="#Footnote_7_61" class="fnanchor">[7]</a>
+Since then the condition and form of the
+mountain has remained very much the same, varied
+only by the results of occasional eruptions.</p>
+
+<p>(<i>d.</i>) <i>Dissimilarity in the Constitution of the Lavas
+of Etna and Vesuvius.</i>&mdash;Before leaving the subject we
+have been considering, it is necessary that I should
+mention one remarkable fact connected with the origin
+of the lavas of Etna and Vesuvius respectively; I refer
+to their essential differences in mineral composition.
+It might at first sight have been supposed that
+the lavas of these two volcanic mountains&mdash;situated
+at such a short distance from each other, and evidently
+along the same line of fracture in the crust&mdash;would be
+of the same general composition; but such is not the
+case. In the lava of Vesuvius leucite is an essential,
+and perhaps the most abundant mineral. It is called
+by Zirkel <i>Sanidin-Leucitgestein</i>. (See <a href="#PLATE_4">Plate IV</a>.)
+But in that of Etna this mineral is (as far as I am
+aware) altogether absent. We have fortunately
+abundant means of comparison, as the lavas of
+these two mountains have been submitted to close
+examination by petrologists. In the case of the
+Vesuvian lavas, an elaborate series of chemical
+analyses and microscopical observations have been
+<span class="pagenum"><a name="Page_68" id="Page_68">[Pg 68]</a></span>made by the Rev. Professor Haughton, of Dublin
+University, and the author,<a name="FNanchor_8_62" id="FNanchor_8_62"></a><a href="#Footnote_8_62" class="fnanchor">[8]</a> from specimens collected
+by Professor Guiscardi from the lava-flows extending
+from 1631 to 1868, in every one of which
+leucite occurs, generally as the most abundant
+mineral, always as an essential constituent. On
+the other hand, the composition of the lavas of
+Etna, determined by Professor A. von Lasaulx, from
+specimens taken from the oldest (vorätnäischen) sheets
+of lava down to those of the present day, indicates
+a rock of remarkable uniformity of composition, in
+which the components are plagioclase felspar, augite,
+olivine, magnetite, and sometimes apatite; but of
+leucite we have no trace.<a name="FNanchor_9_63" id="FNanchor_9_63"></a><a href="#Footnote_9_63" class="fnanchor">[9]</a> In fact, the lavas of Etna
+are very much the same in composition as the ordinary
+basalts of the British Isles, while those of Vesuvius
+are of a different type. This seems to suggest an
+origin of the two sets of lavas from a different deep-seated
+magma; the presence of leucite in such large
+quantity requiring a magma in which soda is in
+excess, as compared with that from which the lavas
+of Etna have been derived.<a name="FNanchor_10_64" id="FNanchor_10_64"></a><a href="#Footnote_10_64" class="fnanchor">[10]</a></p>
+
+<div class="footnote"><p><a name="Footnote_1_55" id="Footnote_1_55"></a><a href="#FNanchor_1_55"><span class="label">[1]</span></a> <i>Mémoires pour Servir</i>, etc., vol. ii.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_56" id="Footnote_2_56"></a><a href="#FNanchor_2_56"><span class="label">[2]</span></a> Daubeny, <i>Volcanoes</i>, p. 270.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_57" id="Footnote_3_57"></a><a href="#FNanchor_3_57"><span class="label">[3]</span></a> Von Waltershausen, <i>Der Ætna</i>, edited by A. von Lasaulx.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_58" id="Footnote_4_58"></a><a href="#FNanchor_4_58"><span class="label">[4]</span></a> Lyell, <i>Principles of Geology</i>, vol. ii., edition 1872.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_59" id="Footnote_5_59"></a><a href="#FNanchor_5_59"><span class="label">[5]</span></a> Its height, as determined by Captain Smyth in 1875 trigonometrically,
+was 10,874 feet, and afterwards by Sir J. Herschel barometrically,
+10,872 feet.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_60" id="Footnote_6_60"></a><a href="#FNanchor_6_60"><span class="label">[6]</span></a> <i>Atlas des Ætna</i> (Weimar, 1858), in which the different lava-streams
+of 1688, 1802, 1809, 1811, 1819, 1824, and 1838 are delineated.</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_61" id="Footnote_7_61"></a><a href="#FNanchor_7_61"><span class="label">[7]</span></a> Sir William Hamilton observes that history is silent regarding the
+first eruptions of Etna. It was in activity before the Trojan War, and
+even before the arrival of the "Sizilien" settlers. Diodorus and
+Thucydides notice the earliest recorded eruptions, those from 772 to
+388 <span class="smcap">B.C.</span>, during which time the mountain was thrice in eruption.
+Later eruptions took place in the year <span class="smcap">140, 135, 125, 122 B.C.</span> In the
+year 44 <span class="smcap">B.C.</span>, in the reign of Julius Cæsar, there was a very violent outburst
+of volcanic activity.&mdash;<i>Neuere Beobachtungen über die Vulkane
+Italiens und am Rhein</i>, p. 173, Frankfurt (1784).</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_62" id="Footnote_8_62"></a><a href="#FNanchor_8_62"><span class="label">[8]</span></a> "Report on the Chemical and Mineralogical Characters of the
+Lavas of Vesuvius from 1631 to 1868," <i>Transactions of the Royal Irish
+Academy</i>, vol. xxvi. (1876). In the lava of 1848 leucite was found to
+reach 44.9 per cent. of the whole mass. In that of Granatello, 1631, it
+reaches its lowest proportion&mdash;viz., 3.37 per cent.</p></div>
+
+<div class="footnote"><p><a name="Footnote_9_63" id="Footnote_9_63"></a><a href="#FNanchor_9_63"><span class="label">[9]</span></a> A. von Lasaulx, in Von Waltershausen's <i>Der Ætna</i>, Book II., x.
+423.</p></div>
+
+<div class="footnote"><p><a name="Footnote_10_64" id="Footnote_10_64"></a><a href="#FNanchor_10_64"><span class="label">[10]</span></a> The view of Professor Judd, that leucite easily changes into felspar,
+and that some ancient igneous rocks which now contain felspar were
+originally leucitic, does not seem to be borne out by the above facts.
+In such cases the felspar crystals ought to retain the forms of leucite.
+See <i>Volcanoes</i>, 4th edition, p. 268.</p></div>
+<p><span class="pagenum"><a name="Page_69" id="Page_69">[Pg 69]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_II_CHAPTER_III" id="PART_II_CHAPTER_III"></a>CHAPTER III.
+<br /><br />
+THE LIPARI ISLANDS, STROMBOLI.</h2>
+
+
+<p>(<i>a.</i>) A brief account of this remarkable group of volcanic
+islands must here be given, inasmuch as they seem
+to be representatives of a stage of volcanic action in
+which the igneous forces are gradually losing their
+energy. According to Daubeny, the volcanic action in
+these islands seems to be developed along two lines,
+nearly at right angles to each other, one parallel to
+that of the Apennines, beginning with Stromboli,
+intersecting Panaria, Lipari, and Vulcano; the
+other extending from Panaria to Salina, Alicudi,
+and Felicudi, and again visible in the volcanic
+products which make their appearance at Ustica.
+(See <a href="#FIGURE_11">Map, Fig. 11</a>.) The islands lie between the
+north coast of Sicily and that of Italy, and from
+their position seem to connect Etna with Vesuvius;
+but this is very problematical, as would appear from
+the difference of their lavas. The principal islands
+are those of Stromboli, Panaria, Lipari, Vulcano,
+Salina, Felicudi, and Alicudi. These three last are
+extinct or dormant, but Salina contains a crater, rising,
+according to Daubeny, not less than 3500 feet above
+the sea.<a name="FNanchor_1_65" id="FNanchor_1_65"></a><a href="#Footnote_1_65" class="fnanchor">[1]</a> Vulcano (referred to by Strabo under the
+name of Hiera) consists of a crater which constantly
+<span class="pagenum"><a name="Page_70" id="Page_70">[Pg 70]</a></span>emits large quantities of sulphurous vapours, but was
+in a state of activity in the year 1786, when, after
+frequent earthquake shocks and subterranean noises,
+it vomited forth during fifteen days showers of sand,
+together with clouds of smoke and flame, altering
+materially the shape of the crater from which they
+proceeded.</p>
+
+<div class="figcenter">
+<a name="FIGURE_11">
+<span class="center">LIPARI ISLANDS.</span><br />
+  <img src="images/figure11.jpg" alt="Lipari Islands" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 11.</span>&mdash;Map to show the position of these islands, showing the
+branching lines of volcanic action&mdash;one parallel to that of the Apennines,
+the other stretching westwards at right angles thereto.
+</td></tr>
+</table>
+</div>
+
+<p>The islands of Lipari are formed of beds of tuff,
+penetrated by numerous dykes of lava, from which
+uprise two or three craters, formed of pumice and
+obsidian passing into trachyte. Volcanic operations
+might have here been said to be extinct, were it not
+that their continuance is manifested by the existence
+<span class="pagenum"><a name="Page_71" id="Page_71">[Pg 71]</a></span>of hot springs and "stufes," or vapour baths, at St.
+Calogero, about four miles from the town of Lipari.
+Daubeny considers it not improbable that this island
+may have had an active volcano even within the
+historical period, a view which is borne out by the
+statement of Strabo.<a name="FNanchor_2_66" id="FNanchor_2_66"></a><a href="#Footnote_2_66" class="fnanchor">[2]</a></p>
+
+<div class="figcenter">
+<a name="FIGURE_12">
+  <img src="images/figure12.jpg" alt="Vulcano" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 12.</span>&mdash;Island of Vulcano, one of the Lipari Group, in eruption.&mdash;(After
+Sir W. Hamilton.)
+</td></tr>
+</table>
+</div>
+
+<p>(<i>b.</i>) But by far the most remarkable island of the
+group, as regards its present volcanic condition, is
+Stromboli, which has ever been in active eruption from
+the commencement of history down to the present day.
+Professor Judd, who visited this island in 1874, and
+has produced a striking representation of its aspect,<a name="FNanchor_3_67" id="FNanchor_3_67"></a><a href="#Footnote_3_67" class="fnanchor">[3]</a>
+gives an account of which I shall here avail myself.<a name="FNanchor_4_68" id="FNanchor_4_68"></a><a href="#Footnote_4_68" class="fnanchor">[4]</a>
+<span class="pagenum"><a name="Page_72" id="Page_72">[Pg 72]</a></span>The island is of rudely circular outline, and rises into
+a cone, the summit of which is 3090 feet above the
+level of the Mediterranean. From a point on the side
+of the mountain masses of vapour are seen to issue,
+and these unite to form a cloud over the summit; the
+outline of this vapour-cloud varying continually according
+to the hygrometric state of the atmosphere, and
+the direction and force of the wind. At the time of
+Professor Judd's visit, the vapour-cloud was spread in
+a great horizontal stratum overshadowing the whole
+island; but it was clearly seen to be made up of a
+number of globular masses, each of which is a product
+of a distinct outburst of volcanic forces. Viewed
+at night-time, Stromboli presents a far more striking
+and singular spectacle. When watched from the
+deck of a vessel, a glow of red light is seen to
+make its appearance from time to time above the
+summit of the mountain; it may be observed
+to increase gradually in intensity, and then as
+gradually to die away. After a short interval the
+same appearances are repeated, and this goes on till
+the increasing light of dawn causes the phenomenon
+to be no longer visible. The resemblance presented
+by Stromboli to a "flashing light" on a most gigantic
+scale is very striking, and the mountain has long
+been known as "the lighthouse of the Mediterranean."</p>
+
+<p>The mountain is built up of ashes, slag, and scoriæ,
+to a height of (as already stated) over 3000 feet above
+the surface of the sea; but, as Professor Judd observes,
+this by no means gives a just idea of its vast bulk.
+Soundings in the sea surrounding the island show
+that the bottom gradually shelves around the shores
+to a depth of nearly 600 fathoms, so that Stromboli is
+a great conical mass of cinders and slaggy materials,
+<span class="pagenum"><a name="Page_73" id="Page_73">[Pg 73]</a></span>having a height above its floor of about 6600 feet,
+and a base the diameter of which exceeds four miles.</p>
+
+<p>The crater of Stromboli is situated, not at the apex
+of the cone, but at a distance of 1000 feet below it.
+The explosions of steam, accompanied by the roaring
+as of a smelting furnace, or of a railway engine when
+blowing off its steam, are said by Judd to take place
+at very irregular intervals of time, "varying from less
+than one minute to twenty minutes, or even more."
+On the other hand, Hoffmann describes them as
+occurring at "perfectly regular intervals," so that,
+perhaps, some variation has taken place within the
+interval of about forty years between each observation.
+Both observers agree in stating that lava is to
+be seen welling up from some of the apertures within
+the crater, and pouring down the slope towards the
+sea, which it seldom or never reaches.<a name="FNanchor_5_69" id="FNanchor_5_69"></a><a href="#Footnote_5_69" class="fnanchor">[5]</a> The intermittent
+character of these eruptions appears to be
+due, as Mr. Scrope has suggested, to the exact proportion
+between the expansive and repressive forces;
+the expansive force arising from the generation of a
+certain amount of aqueous vapour and of elastic gas;
+the repressive, from the pressure of the atmosphere
+and from the weight of the superincumbent volcanic
+products. Steam is here, as in a steam-engine, not
+the originating agent in the phenomena recorded;
+but the result of water coming in contact with
+molten lava constantly welling up from the interior,
+by which it is converted into steam, which from time
+to time acquires sufficient elastic force to produce the
+eruptions; the water being obviously derived from
+the surrounding sea, which finds its way by filtration
+through fissures, or through the porous mass of which
+<span class="pagenum"><a name="Page_74" id="Page_74">[Pg 74]</a></span>the mountain is formed. Were it not for the access
+of water this volcano would probably appear as a
+fissure-cone extruding a small and continuous stream
+of molten lava. The adventitious access of the sea
+water gives rise to the phenomena of intermittent
+explosions. The vitality of the volcano is therefore
+due, not to the presence of water, but to the welling
+up of matter from the internal reservoir through the
+throat of the volcano.</p>
+
+<p><i>Pantelleria.</i>&mdash;This island, lying between the coast
+of Sicily and Cape Bon in Africa, is wholly volcanic.
+It has a circumference of thirty miles, and from its
+centre rises an extinct crater-cone to a height of about
+3000 feet. The flanks of this volcano are diversified
+by several fresh craters and lava-streams, while hot
+springs burst out with a hissing noise on its southern
+flank, showing that molten matter lies below at no
+very great depth.</p>
+
+<p>This island probably lies along the dividing line
+between the non-volcanic and volcanic region of the
+Mediterranean, and is consequently liable to intermittent
+eruptions. It was at a short distance from
+this island that the remarkable submarine outburst
+of volcanic forces took place on October 17th, 1891,
+for an account of which we are indebted to Colonel
+J. C. Mackowen.<a name="FNanchor_6_70" id="FNanchor_6_70"></a><a href="#Footnote_6_70" class="fnanchor">[6]</a> On that day, after a succession of
+earthquake shocks, the inhabitants were startled by
+observing a column of "smoke" rising out of the sea at
+a distance of three miles, in a north-westerly direction.
+<span class="pagenum"><a name="Page_75" id="Page_75">[Pg 75]</a></span>The Governor, Francesco Valenza, having manned a
+boat, rowed out towards the fiery column, and on
+arriving found it to consist of black scoriaceous bombs,
+which were being hurled into the air to a height of
+nearly thirty yards; some of them burst in the air,
+others, discharging steam, ran hissing over the water;
+many of them were very hot, some even red-hot. One
+of these bombs, measuring two feet in diameter, was
+captured and brought to shore. It was observed that
+after the eruption the earthquake shocks ceased. A
+vast amount of material was cast out of the submarine
+crater, forming an island 500 yards in length
+and rising up to nine feet above the surface, but after
+a few days it was broken up and dispersed over
+the sea-bed by the action of the waves.</p>
+
+<div class="footnote"><p><a name="Footnote_1_65" id="Footnote_1_65"></a><a href="#FNanchor_1_65"><span class="label">[1]</span></a> <i>Volcanoes</i>, p. 262. These islands are described by Hoffmann,
+<i>Poggendorf Annal.</i>, vol. xxvi. (1832); also by Lyell, <i>Principles of
+Geology</i>, vol. ii., and by Judd, who personally visited them, and gives
+a very vivid account of their appearance and structure.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_66" id="Footnote_2_66"></a><a href="#FNanchor_2_66"><span class="label">[2]</span></a> Strabo, lib. vi.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_67" id="Footnote_3_67"></a><a href="#FNanchor_3_67"><span class="label">[3]</span></a> Judd, <i>Volcanoes</i>, p. 8.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_68" id="Footnote_4_68"></a><a href="#FNanchor_4_68"><span class="label">[4]</span></a> Stromboli has also been described by Spallanzani, Hoffmann,
+Daubeny, and others. The account of Judd is the most recent. Of
+this island Strabo says, "Strongyle a rotundate figuræ sic dicta, ignita
+ipsa quoque, violentia flammarum minor, fulgore excellens; ibi habitasse
+Æcolum ajunt."&mdash;Lib. vi.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_69" id="Footnote_5_69"></a><a href="#FNanchor_5_69"><span class="label">[5]</span></a> <i>Poggend. Annal.</i>, vol. xxvi., quoted by Daubeny.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_70" id="Footnote_6_70"></a><a href="#FNanchor_6_70"><span class="label">[6]</span></a> Communicated by Captain Petrie to the Victoria Institute, 1st
+February 1892. See also a detailed and illustrated account of the
+eruption communicated by A. Ricco to the <i>Annali dell' Ufficio centrale
+Meteorologico e Geodonamico</i>, Ser. ii., Parte 3, vol. xi. Summarised by
+Mr. Butler in <i>Nature</i>, April 21, 1892.</p></div>
+<p><span class="pagenum"><a name="Page_76" id="Page_76">[Pg 76]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_II_CHAPTER_IV" id="PART_II_CHAPTER_IV"></a>CHAPTER IV.
+<br /><br />
+THE SANTORIN GROUP.</h2>
+
+
+<div class="figcenter">
+<a name="FIGURE_13">
+  <img src="images/figure13.jpg" alt="Section of Santorin" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 13.</span>&mdash;Ideal Section through the Gulf of Santorin, to show the
+structure of the submerged volcano.&mdash;<i>a.</i> Island of Aspronisi; <i>b.</i> Island
+of Thera; 1. Old Kaimeni Island; 2. New Kaimeni Island; 3. Little
+Kaimeni Island.
+</td></tr>
+</table>
+</div>
+
+<p>(<i>a.</i>) Before leaving the subject of European active
+volcanoes, it is necessary to give some account of the
+remarkable volcanic island of Santorin, in the Grecian
+archipelago. This island for 2000 years has been the
+scene of active volcanic operations, and in its outline
+and configuration, both below and above the surface
+of the Mediterranean, presents the aspect of a
+partially submerged volcanic mountain. (See <a href="#FIGURE_13">Section,
+Fig. 13</a>.) If, for example, we can imagine the waters
+of the sea to rise around the flanks of Vesuvius until
+they have entered and overflowed to some depth the
+interior caldron of Somma, thus converting the old
+crater into a crescent-shaped island, and the cone of
+Vesuvius into an island&mdash;or group of islands&mdash;within
+<span class="pagenum"><a name="Page_77" id="Page_77">[Pg 77]</a></span>the caldron, then we shall form some idea of the
+appearance and structure of the Santorin group.</p>
+
+<p><i>Form of the Group.</i>&mdash;The principal island, Thera,
+has somewhat the shape of a crescent, breaking off in
+a precipitous cliff on the inner side, but on the outer
+side sloping at an angle of about fifteen degrees into
+deep water. Continuing the curvature of the crescent,
+but separated by a channel, is the island of Therasia;
+and between this and the southern promontory of
+Thera is another island called Aspronisi. All these
+islands, if united, would form the rim of a crater, in
+which the volcanic matter slopes outward into deep
+water, descending at a short distance to a depth
+of 200 fathoms and upwards. In the centre of the
+gulf thus formed rise three islands, called the Old,
+New, and Little Kaimenis. These may be regarded as
+cones of eruption, which history records as having
+been thrown up at successive intervals. According to
+Pliny, the year 186 <span class="smcap">B.C.</span> gave birth to Old Kaimeni,
+also called Hiera, or the Sacred Isle; and in the first
+year of our era Thera (the Divine) made its appearance
+above the water, and was soon joined to the
+older island by subsequent eruptions. Old Kaimeni
+also increased in size by the eruptions of 726 and
+1427. A century and a half later, in 1573, another
+eruption produced the cone and crater called Micra-Kaimeni.
+Thus were formed, or rather were rendered
+visible above the water, the central craters of eruption;
+and between these and the inner cliff of Thera
+and Therasia is a ring of deep water, descending to a
+depth of over 200 fathoms. So that, were these islands
+raised out of the sea, we should have presented to our
+view a magnificent circular crater about six miles in
+diameter, bounded by nearly vertical walls of rock
+<span class="pagenum"><a name="Page_78" id="Page_78">[Pg 78]</a></span>from 1000 to 1500 feet in height, and ruptured at one
+point, from the centre of which would rise two volcanic
+cones&mdash;namely, the Kaimenis&mdash;one with a double
+crater, still foci of eruption, and from time to time
+bursting forth in paroxysms of volcanic energy, of
+which those of 1650, 1707, and 1866 were the most
+violent and destructive.<a name="FNanchor_1_71" id="FNanchor_1_71"></a><a href="#Footnote_1_71" class="fnanchor">[1]</a> Of this last I give a bird's-eye
+view (<a href="#FIGURE_14">Fig. 14</a>).</p>
+
+<p>The only rock of non-volcanic origin in these
+islands consists of granular limestone and clay slate
+forming the ridge of Mount St. Elias, which rises to
+a height of 1887 feet at the south-eastern side of
+the island of Thera, crossing the island from its
+outer margin nearly to the interior cliff, so that the
+volcanic materials have been piled up along its sides.
+The rocks of St. Elias are much more ancient than
+any of the volcanic materials around; and, as Bory
+St. Vincent has shown, have been subjected to the
+same flexures, dip and strike, as those sedimentary
+rocks which go to form the non-volcanic islands of
+the Grecian archipelago.</p>
+
+<p><span class="pagenum"><a name="Page_79" id="Page_79">[Pg 79]</a></span></p>
+
+<div class="figcenter">
+<a name="FIGURE_14">
+  <img src="images/figure14.jpg" alt="Gulf of Santorin" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 14.</span>&mdash;Bird's-eye View of the Gulf of Santorin during the volcanic eruption of February 1866.&mdash;(After Lyell.)
+<p><span class="pagenum"><a name="Page_80" id="Page_80">[Pg 80]</a></span></p>
+</td></tr>
+</table>
+</div>
+
+<div class="figcenter">
+<a name="FIGURE_15">
+  <img src="images/figure15.jpg" alt="Rocca Monfina" />
+</a>
+<p class="center"><i>Ground Plan of Rocca Monfina</i></p>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 15.</span>&mdash;Rocca Monfina, in Southern Italy, showing a crater-ring
+of trachytic tuffs, from the midst of which, according to Judd, an andesite
+lava-cone has been built up. Compare with the Santorin Group.
+</td></tr>
+</table>
+</div>
+
+<p>(<i>b.</i>) <i>Origin of the Santorin Group.</i>&mdash;In reference to
+the origin of the Santorin group, Lyell regards it
+as a remnant of a great volcanic mountain which
+possessed a focus of eruption rising in the position
+of the present foci, but afterwards partially destroyed
+and the whole submerged to a depth of over 1000
+feet. But another explanation is open to us, and
+one not inconsistent with what we now know of
+the physical changes to which the Mediterranean has
+been subjected since early Tertiary times. To my
+mind it is difficult to conceive how such a volcanic
+mountain as that of Santorin could have been formed
+under water; while, on the other hand, its physical
+structure and contour bear so striking a resemblance
+(as already observed) to those of Vesuvius and Rocca
+Monfina that we are much tempted to infer that it
+had a somewhat similar origin. Now we know that
+Vesuvius was built up by means of successive eruptions
+taking place under the air; and the question arises
+whether it could be possible that Santorin had a similar
+origin owing to the waters of the Mediterranean
+having been temporally lowered at a later Tertiary
+epoch. It has been stated by M. Fouqué that the
+age of the more ancient volcanic beds of Santorin
+belong, as shown by the included fossils, to the
+<span class="pagenum"><a name="Page_81" id="Page_81">[Pg 81]</a></span>newer Pliocene epoch. These are of course the
+unsubmerged, and therefore more recent strata, and
+may have been recently upheaved during one or more
+of the outbursts of volcanic energy. But it seems
+an impossibility that the Gulf of Santorin, with its
+precipitous walls and deep circular interior channel,
+as shown by the Ideal Section (<a href="#FIGURE_13">Fig. 13</a>), could have
+been formed otherwise than under the air. We are
+led, therefore, to inquire whether there was a time
+in the history of the Mediterranean, since the Eocene
+period, when the waters were lower than at present.
+That this was the case we have clear evidence. The
+remains of elephants, hippopotami, and other animals,
+which have been discovered in great numbers in the
+Maltese caves, show that this island was united to
+Sicily, and this again to Europe, during the later
+Pliocene epoch, so as to have become the abode of
+an Europasian fauna. According to Dr. Wallace, a
+causeway of dry land existed, stretching from Italy to
+Tunis in North Africa through the Maltese Islands&mdash;an
+inference involving the lowering of the waters of the
+Mediterranean by several hundred feet.<a name="FNanchor_2_72" id="FNanchor_2_72"></a><a href="#Footnote_2_72" class="fnanchor">[2]</a> There is
+every reason for supposing that the old volcano of
+Santorin was in active eruption at this period; and
+its history may be considered to be similar to that of
+Vesuvius until, at the rising of the waters during the
+Pluvial (or Post-Pliocene) epoch, during which they
+rose higher than at present, Santorin was converted
+into a group of islands, slightly differing in form from
+those of the present day. This view seems to meet the
+difficulties regarding the origin of this group, difficulties
+which Lyell had long since clearly recognised.</p>
+
+<p><span class="pagenum"><a name="Page_82" id="Page_82">[Pg 82]</a></span></p><p>(<i>c.</i>) <i>Limit of the Mediterranean Volcanic Region.</i>&mdash;With
+the Santorin group we conclude our account of
+the active European volcanoes. It may be observed,
+however, that from some cause not ascertained the volcanic
+districts of the Mediterranean and its shores are
+confined to the north side of that great inland sea; so
+that as regards vulcanicity the African coast presents
+a striking contrast to that of the opposite side. If we
+draw a line from the shores of the Levant to the
+Straits of Gibraltar, by Candia, Malta, and to the
+south of Pantelleria and Sardinia, we shall find that
+the volcanic islands and districts of the mainland lie
+to the north of it.<a name="FNanchor_3_73" id="FNanchor_3_73"></a><a href="#Footnote_3_73" class="fnanchor">[3]</a> This has doubtless some connection
+with the internal geological structure. The
+immunity of the Libyan desert from volcanic irruptions
+is in keeping with the remarkably undisturbed
+condition of the Secondary strata, which seldom
+depart much from the horizontal position; while the
+igneous rocks of the Atlas mountains are probably of
+great geological antiquity. On the other hand, the
+Secondary and Tertiary formations of the northern
+shores and islands of the Mediterranean are generally
+characterised by the highly-inclined, flexured, and
+folded position of the strata. Hence we may
+suppose that the crust over the region lying to the
+north of the volcanic line, owing to its broken and
+<span class="pagenum"><a name="Page_83" id="Page_83">[Pg 83]</a></span>ruptured condition, was less able to resist the
+pressure of the internal forces of eruption than that
+lying to the south of it; and that, in consequence,
+vents and fissures of eruption were established over
+the former of these regions, while they are absent in
+the latter.</p>
+
+<div class="footnote"><p><a name="Footnote_1_71" id="Footnote_1_71"></a><a href="#FNanchor_1_71"><span class="label">[1]</span></a> Fuller details will be found in Daubeny's <i>Volcanoes</i>, chap. xviii.,
+and Lyell's <i>Principles of Geology</i>, vol. ii. p. 65 (edition 1872). The
+bird's-eye view is taken from this latter work by kind permission of the
+publisher, Mr. J. Murray, as also the accompanying Ideal Section,
+<a href="#FIGURE_13">Fig. 13</a>.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_72" id="Footnote_2_72"></a><a href="#FNanchor_2_72"><span class="label">[2]</span></a> Wallace, <i>Geographical Distribution of Animals</i> (1876). The
+author's <i>Sketch of Geological History</i>, p. 130 (Deacon &amp; Co., 1887).</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_73" id="Footnote_3_73"></a><a href="#FNanchor_3_73"><span class="label">[3]</span></a> The <i>volcanic area</i> lying to the north of this line will include
+Sardinia, Sicily, Pantelleria, the Grecian Archipelago, Asia Minor, and
+Syria; the <i>non-volcanic area</i> lying to the south of this line will include
+the African coast, Malta, Isles of Crete and Cyprus. The Isle of
+Pantelleria is apparently just on the line, which, continued eastward,
+probably follows the north coast of Cyprus, parallel to the strike
+of the strata and of the central axis of that island.&mdash;See "Carte
+Géologique de l'île de Chypre, par MM. Albert Gaudry et Amedée
+Damour" (1860).</p></div>
+<p><span class="pagenum"><a name="Page_84" id="Page_84">[Pg 84]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_II_CHAPTER_V" id="PART_II_CHAPTER_V"></a>CHAPTER V.
+<br /><br />
+EUROPEAN EXTINCT OR DORMANT VOLCANOES.</h2>
+
+
+<p>We are naturally led on from a consideration of the
+active volcanoes of Europe to that of volcanoes which
+are either dormant or extinct in the same region.
+Such are to be found in Italy, Central France,
+both banks of the Rhine and Moselle, the Westerwald,
+Vogelsgebirge, and other districts of Germany;
+in Hungary, Styria, and the borders of the Grecian
+archipelago. But the subject is too large to be
+treated here in detail; and I propose to confine my
+observations to some selected cases which are to be
+found in Southern Italy, Central France, and the
+Rhenish districts, where the volcanic features are of
+so recent an age as to preserve their outward form
+and structure almost intact.</p>
+
+<p>(<i>a.</i>) <i>Southern Italy.</i>&mdash;Extinct volcanoes and volcanic
+rocks occupy considerable tracts between the western
+flanks of the Apennines and the Mediterranean coast
+in the Neapolitan and Roman States, forming the
+remarkable group of the Phlegræan fields (Campi
+Phlegræi), with the adjoining islands of Ischia,
+Procida, Nisida, Vandolena, Ponza, and Palmarola;
+at Melfi and Avellino. All the region around Rome
+extending along the western slopes of the Apennines
+from Velletri to Orvieto, together with Mount Annato
+<span class="pagenum"><a name="Page_85" id="Page_85">[Pg 85]</a></span>in Tuscany, is formed of volcanic material, and the
+same may be said of a large part of the island of
+Sardinia. From these districts I shall select some
+points which seem to be of special interest.</p>
+
+<p><i>Monte Nuovo and the Phlegræan Fields.</i>&mdash;The tract
+of which this celebrated district forms a part lies as
+it were in a bay of the Apennine limestone of Jurassic
+age. The floor of this bay is composed of puzzolana,
+a name given to beds of volcanic tuff of great thickness,
+and rising into considerable hills in the vicinity
+of the city of Naples, such as that of St. Elmo. Its
+composition is peculiar, as it is chiefly formed of
+small pieces of pumice, obsidian, and trachyte, in beds
+alternating with loam, ferriferous sand, and fragments
+of limestone. It is evidently of marine formation,
+as Sir William Hamilton, Professor Pilla, and others
+have detected sea-shells therein, of the genera <i>Ostræa</i>,
+<i>Cardium</i>, <i>Pecten</i> and <i>Pectunculus</i>, <i>Buccinum</i>, etc. It
+is generally of a greyish colour, and sometimes
+sufficiently firm to be used as a building stone. The
+Roman Campagna is largely formed of similar
+materials, which were deposited at a time when the
+districts in question were submerged, and matter was
+being erupted from volcanic vents at various points
+around, and spread over the sea-bed.</p>
+
+<p>Such is the character of the general floor on
+which the more recent crater-cones of this district
+have been built. These are numerous, and all
+extinct with the exception of the Solfatara, near
+Puzzuoli, from which gases mixed with aqueous
+vapour are continually being exhaled. The gases
+consist of sulphuretted hydrogen mixed with a minute
+quantity of muriatic acid.<a name="FNanchor_1_74" id="FNanchor_1_74"></a><a href="#Footnote_1_74" class="fnanchor">[1]</a> This district is also
+<span class="pagenum"><a name="Page_86" id="Page_86">[Pg 86]</a></span>remarkable for containing several lakes occupying
+the interiors of extinct craters; amongst others, Lake
+Avernus, which, owing to its surface having been
+darkened by forests, and in consequence of the
+effluvia arising from its stagnant waters, has had
+imparted to it a character of gloom and terror, so
+that Homer in the <i>Odyssey</i> makes it the entrance to
+hell, and describes the visit of Ulysses to it. Virgil
+follows in his steps. Another lake of similar origin
+is Lake Agnano. Here also is the Grotto del Cane,
+a cavern from which are constantly issuing volumes
+of carbonic acid gas combined with much aqueous
+vapour, which is condensed by the coldness of the
+external air, thus proving the high temperature of
+the ground from which the gaseous vapour issues.
+This whole volcanic region, so replete with objects
+of interest,<a name="FNanchor_2_75" id="FNanchor_2_75"></a><a href="#Footnote_2_75" class="fnanchor">[2]</a> may be considered, as regards its volcanic
+character, in a moribund condition; but that it is
+still capable of spasmodic movement is evinced by
+the origin of Monte Nuovo, the most recent of the
+crater-cones of the district. This mountain, rising
+from the shore of the Bay of Baiæ, was suddenly
+formed in September 29th, 1538, and rises to a height
+of 440 feet above the sea-level. It is a crater-cone,
+and the depth of the crater has been determined by
+the Italian mineralogist Pini to be 421 English feet;
+its bottom is thus only 19 feet above the sea-level. A
+portion of the base of the cone is considered partly
+to occupy the site of the Lucrine Lake, which was
+itself nothing more than the crater of a pre-existent
+<span class="pagenum"><a name="Page_87" id="Page_87">[Pg 87]</a></span>volcano, and was almost entirely filled up during the
+explosion of 1538. Monte Nuovo is composed of
+ashes, lapilli, and pumice-stones; and its sudden
+formation, heralded by earthquakes, and accompanied
+by the ejection of volcanic matter mixed with fire
+and water, is recorded by Falconi, who vividly depicts
+the terror and consternation of the inhabitants of the
+surrounding country produced by this sudden and
+terrible outburst of volcanic forces.<a name="FNanchor_3_76" id="FNanchor_3_76"></a><a href="#Footnote_3_76" class="fnanchor">[3]</a></p>
+
+<p>(<i>b.</i>) <i>Central Italy and the Roman States.</i>&mdash;The tract
+bordering the western slopes of the Apennines northward
+from Naples into Tuscany, and including the
+Roman States, is characterised by volcanic rocks and
+physical features of remarkable interest and variety.
+These occur in the form of extinct craters, sometimes
+filled with water, and thus converted into circular
+lakes; or of extensive sheets and conical hills of tuff;
+or, finally, of old necks and masses of trachyte and
+basalt, sometimes exhibiting the columnar structure.
+The Eternal City itself is built on hills of
+volcanic material which some observers have supposed
+to be the crater of a great volcano; but
+Ponzi, Brocchi, and Daubeny all concur in the
+opinion that this is not the case, as will clearly
+appear from the following account.</p>
+
+<p>The geological structure of the valley of the Tiber
+at Rome is very clearly described by Professor Ponzi
+in a memoir published in 1850, from which the
+accompanying section is taken.<a name="FNanchor_4_77" id="FNanchor_4_77"></a><a href="#Footnote_4_77" class="fnanchor">[4]</a> (<a href="#FIGURE_16">Fig. 16</a>.) From
+this it will be seen that "the Seven-hilled City"
+<span class="pagenum"><a name="Page_88" id="Page_88">[Pg 88]</a></span>is built upon promontories of stratified volcanic tuff,
+of which the Campagna is formed, breaking off along
+the banks of the Tiber, the hills being the result of
+the erosion, or denudation, of the strata along the side
+of the river valley. As the strata dip from west to
+east across the course of the river, it follows that
+those on the western banks are below those on the
+opposite side; and thus the marine sands and marls
+which underlie the volcanic tuff, and are concealed
+by it along the eastern side of the valley, emerge on
+the west, and form the range of hills on that side.
+Such being the structure of the formations under
+Rome, it is evident that it is not "built on a
+volcano."</p>
+
+<div class="figcenter">
+<a name="FIGURE_16">
+  <img src="images/figure16.jpg" alt="Valley of Tiber" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 16.</span>&mdash;Geological Section across the Valley of the Tiber at Rome.
+1. Alluvium of the Tiber; 2. Diluvium; 3. Volcanic tuff (recent
+deposits); 4. Sands, etc.; 5. Blue marl (sub-Apennine deposits).
+</td></tr>
+</table>
+</div>
+
+
+<p>The tuff contains fragments of lava and pebbles
+of Apennine limestone, and was deposited under
+the waters of an extensive lake at a time when
+volcanic action was rife amidst the Alban Hills.
+This lacustrine formation rests in turn on deposits
+of marine origin, containing oysters, patellæ, and
+other sea-shells, of which the chain of hills on the
+right bank of the Tiber is chiefly formed.</p>
+
+<p>The district around Albano lying to the south of
+Rome is of peculiar interest from the assemblage of
+old crater-lakes which it contains; as, for instance,
+<span class="pagenum"><a name="Page_89" id="Page_89">[Pg 89]</a></span>those of Albano, Vallariccia, Nemi, Juturna, and the
+lake of Gabii. The lake of Albano, one of the most
+beautiful sheets of water in the world, is about six
+miles in circumference, and surrounded by beds of
+peperino, a variety of tuff presenting a bright, undecomposed
+aspect when newly broken. The level of
+this lake was lowered by the Romans during the
+siege of Veii by means of a tunnel, so that the waters
+are 200 feet lower than the level at which they
+originally stood. In the same district is the lake of
+Nemi, very regular in its circular outline; that of
+Juturna lying near the foot of the Alban Hills, and
+that of Ariccia lying in a deep hollow eight miles in
+circumference;&mdash;all may be supposed to have been the
+craters of extinct volcanoes, both by reason of their
+shape and of the materials of which they are formed.
+All these old craters are, however, according to
+Daubeny, "only the dependencies and offshoots, as
+it were, of the great extinct volcano, the traces of
+which still remain upon the summit of the Alban
+Hills, and which is comparable in its form to that
+of Vesuvius, as it is surrounded by an outer circle
+of volcanic rock comparable to that of Somma."<a name="FNanchor_5_78" id="FNanchor_5_78"></a><a href="#Footnote_5_78" class="fnanchor">[5]</a></p>
+
+<p>To the north of the city of Rome are several crateriform
+lakes, some of which are of great size, such as
+that of Bolsena, over twenty miles in circumference,
+and the Lago di Bracciano, almost as large, and lying
+about twelve miles from the city. These extensive
+sheets of water are surrounded by banks of tuff and
+volcanic sand, in which fragments of augite, leucite,
+and crystals of titanite are distributed. The town of
+Viterbo is built up at the foot of a steep hill called
+Monte Cimini, the lower part of which is composed
+<span class="pagenum"><a name="Page_90" id="Page_90">[Pg 90]</a></span>of trachyte; this is surmounted by tuff, which appears
+to have been ejected from an extinct crater
+occupying the summit of the mountain, and now
+converted into a lake called the Lake of Vico. This
+crater is perfectly circular, and from its centre rises a
+little conical hill covered by trees.</p>
+
+<p>(<i>c.</i>) <i>Physical History.</i>&mdash;Space does not permit of a
+fuller description of the remarkable volcanic features
+of the tract lying along the western slope of the
+Apennines; but from what has been stated it will be
+clear that volcanic forces have been in operation at one
+time on a grand scale in the Roman States and the
+South of Tuscany, over a tract extending from Mount
+Annato to Velletri and Segni.</p>
+
+<p>This tract was separated from that of the Neapolitan
+volcanic region by a range of limestone
+hills of Jurassic age between Segni and Gaeta, a
+protrusion of the Alban Hills westward; but the
+general structure and physical history of both regions
+are probably very similar, with the exception that the
+igneous forces still retain their vitality in the more
+southerly region. In the case of the Roman volcanic
+district, a bay seems to have been formed about the
+close of the Miocene period, bounded on all sides but
+the west by hills of limestone, over whose bed strata
+of marl, sandstone, and conglomerate were deposited.
+This tract was converted by subsequent movements
+into a fresh-water lake, and contemporaneously
+volcanic operations commenced over the whole
+region, and beds of tuff, often containing blocks of
+rock ejected from neighbouring craters, were deposited
+over those of marine origin. Meanwhile numerous
+crater-cones were thrown up; and, as the land gradually
+rose, the waters of the lake were drained off,
+<span class="pagenum"><a name="Page_91" id="Page_91">[Pg 91]</a></span>leaving dry the Campagna and plain of the Tiber.
+Ultimately the volcanic fires smouldered down and
+died out, whether within the historic epoch or not
+is uncertain; lakes were formed within the now
+dormant craters, and the face of nature gradually
+assumed a more placid and less forbidding aspect
+over this memorable region, destined to be the site
+of Rome, the Mistress of the World.</p>
+
+<div class="footnote"><p><a name="Footnote_1_74" id="Footnote_1_74"></a><a href="#FNanchor_1_74"><span class="label">[1]</span></a> As determined by Daubeny in 1825.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_75" id="Footnote_2_75"></a><a href="#FNanchor_2_75"><span class="label">[2]</span></a> Including the ruins of the Temple of Serapis, whose pillars are
+perforated by marine boring shells up to a height of about 16 feet from
+their base; indicating that the land had sunk down beneath the sea,
+and afterwards been elevated to its present level.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_76" id="Footnote_3_76"></a><a href="#FNanchor_3_76"><span class="label">[3]</span></a> The account of Falconi, and another by Pietro Giacomo di Toledo,
+are given by Sir W. Hamilton, <i>op. cit.</i>, p. 198, and also reproduced
+by Sir C. Lyell, <i>Principles</i>, vol. i. p. 608.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_77" id="Footnote_4_77"></a><a href="#FNanchor_4_77"><span class="label">[4]</span></a> Guiseppe Ponzi, "Sulla storia fisica del Bacino di Roma,"
+<i>Annali di Scienze Fisiche</i> (Roma, 1850).</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_78" id="Footnote_5_78"></a><a href="#FNanchor_5_78"><span class="label">[5]</span></a> Daubeny, <i>Volcanoes</i>, p. 171.</p></div>
+<p><span class="pagenum"><a name="Page_92" id="Page_92">[Pg 92]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_II_CHAPTER_VI" id="PART_II_CHAPTER_VI"></a>CHAPTER VI.
+<br /><br />
+EXTINCT VOLCANOES OF CENTRAL FRANCE.</h2>
+
+
+<p>(<i>a.</i>) <i>General Structure of the Auvergne District.</i>&mdash;From
+a granitic and gneissose platform situated near
+the centre of France, and separated from the western
+spurs of the Alps by the wide valley of the Rhone,
+there rises a group of volcanic mountains surpassing
+in variety of form and structure any similar mountain
+group in Europe, and belonging to an epoch ranging
+from the Middle Tertiary down almost to the present
+day. This volcanic group of mountains gives rise to
+several important rivers, such as the Loire, the Allier,
+the Soule (a branch of the Loire), the Creuse, the
+Dordogne, and the Lot; and in the Plomb du Cantal
+attains an elevation of 6130 feet above the sea. Its
+southern section, that of Mont Dore, the Cantal,
+and the Haute Loire, is characterised by magnificent
+valleys, traversing plateaux of volcanic lava, and
+exhibiting the results of river erosion on a grand
+scale; while its northern section, that of the Puy de
+Dôme, presents to us a varied succession of volcanic
+crater-cones and domes, with their extruded lava-streams,
+almost as fresh and unchanged in form as
+if they had only yesterday become extinct. A somewhat
+similar, but less important, chain of extinct
+volcanoes also occurs in the Velay and Vivarais,
+<span class="pagenum"><a name="Page_93" id="Page_93">[Pg 93]</a></span>between the upper waters of the Loire and the
+Allier, in the vicinity of the town of Le Puy.<a name="FNanchor_1_79" id="FNanchor_1_79"></a><a href="#Footnote_1_79" class="fnanchor">[1]</a> The
+principal city in this region is Clermont-Ferrand,
+lying near the base of the Puy de Dôme, and ever
+memorable as the birthplace of Blaise Pascal.<a name="FNanchor_2_80" id="FNanchor_2_80"></a><a href="#Footnote_2_80" class="fnanchor">[2]</a></p>
+
+<div class="figcenter">
+<a name="FIGURE_17">
+  <img src="images/figure17.jpg" alt="Generalised Section" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 17.</span>&mdash;Generalised Section through the Puy de Dôme and Vale
+of Clermont, distance about ten miles. The general floor formed of
+granite and gneiss (G); D. Domite-lava of the Puy de Dôme; Sc.
+Cones of ashes and scoriæ; L. Lava-sheets; A. Alluvium of the Vale
+of Clermont and Lake deposits.
+</td></tr>
+</table>
+</div>
+
+<p>The physical structure of this region is on the
+whole very simple. The fundamental rocks consist
+of granite and gneiss passing into schist, all of
+extreme geological antiquity, forming a vast platform
+gradually rising in a southerly direction towards
+<span class="pagenum"><a name="Page_94" id="Page_94">[Pg 94]</a></span>the head waters of the Loire and the Allier in the
+Departments of Haute Loire, Lozère, and Ardèche.
+On this platform are planted the whole of the volcanic
+mountains. (See <a href="#FIGURE_17">Fig. 17</a>.)</p>
+
+<p>The granitic plateau is bounded on the east,
+throughout a distance of about 50 miles, by the
+wide and fertile plain of Clermont, watered by the
+Allier and its numerous branches descending from the
+volcanic mountains, and is about 25 miles in width
+from east to west in the parallel of Clermont, but
+gradually narrowing in a southerly direction, till
+at Brioude it becomes an ordinary mountain ravine.
+The eastern margin of the plain is formed by another
+granitic ridge expanding into a plateau towards the
+south, and joining in with that already described;
+but towards the north and directly east of Clermont
+it forms a high ridge traversed by the railway to St.
+Étienne and Lyons, and descending towards the east
+into the valley of the Loire. No more impressive
+view is to be obtained of the volcanic region than
+that from the summit of this second ridge, on arriving
+there towards evening from the city of Lyons. At
+your feet lies the richly-cultivated plain of Clermont,
+dotted with towns, villages, and hamlets, and decorated
+with pastures, orchards, vineyards, and numerous trees;
+while beyond rises the granitic plateau, breaking off
+abruptly along the margin of the plain, and deeply
+indented by the valleys and gorges along which the
+streams descend to join the Allier. But the chief
+point of interest is the chain of volcanic crater-cones
+and dome-shaped eminences which rise from the
+plateau, amongst which the Puy de Dôme towers
+supreme. Their individual forms stand out in clear and
+sharp relief against the western sky, and gradually
+<span class="pagenum"><a name="Page_95" id="Page_95">[Pg 95]</a></span>fade away towards the south into the serried masses
+of Mont Dore and Cantal, around whose summits the
+evening mists are gathering. Except the first view
+of the Mont Blanc range from the crest of the Jura,
+there is no scene perhaps which is calculated to
+impress itself more vividly on the memory than that
+here faintly described.<a name="FNanchor_3_81" id="FNanchor_3_81"></a><a href="#Footnote_3_81" class="fnanchor">[3]</a></p>
+
+<div class="figcenter">
+<a name="FIGURE_18"></a>
+<a href="images/figure18full.jpg">
+  <img src="images/figure18.jpg" alt="Transverse view" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 18.</span>&mdash;Transverse view of the Puy de Dôme and neighbouring volcanoes from the Puy de Chopine.&mdash;(After Scrope.)
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_96" id="Page_96">[Pg 96]</a></span></p><p>(<i>b.</i>) <i>The Vale of Clermont.</i>&mdash;The plain upon which
+we look down was once the floor of an extensive lake,
+for it is composed of various strata of sand, clay,
+marl, and limestone, containing various genera and
+species of fresh-water shells. These strata are of
+great thickness, perhaps a thousand feet in some
+places; and along with such shells as <i>Paludina</i>, <i>Planorbis</i>,
+and <i>Limnæa</i> are also found remains of various
+other animals, such as fish, serpents, batrachians,
+crocodiles, ruminants, and those of huge pachyderms,
+as <i>Rhinoceros</i>, <i>Dinotherium</i>, and <i>Cænotherium</i>. This
+great lake, occupying a hollow in the old granitic platform
+of Central France, must have been in existence
+for an extensive period, which MM. Pomel, Aymard,
+and Lyell all unite in referring to that of the Lower
+Miocene. But what is to us of special interest is the
+fact that, in the deposits of this lake of the Haute Loire,
+with the exception of the very latest, there is no intermixture
+of volcanic products such as might have been
+expected to occur if the neighbouring volcanoes
+had been in activity during its existence. Hence it
+may be supposed that, as Scrope suggested, the
+<span class="pagenum"><a name="Page_97" id="Page_97">[Pg 97]</a></span>waters of the lake were drained off owing to the
+disturbance in the levels of the country caused by the
+first explosions of the Auvergne volcanoes.<a name="FNanchor_4_82" id="FNanchor_4_82"></a><a href="#Footnote_4_82" class="fnanchor">[4]</a> If this be
+so, then we possess a key by which to determine the
+period of the first formation of volcanoes in Central
+France; for, as the animal remains enclosed in the
+lacustrine deposits of the Vale of Clermont belong
+to the early Miocene stage, and the earliest traces of
+contemporaneous volcanic <i>ejecta</i> are found only in
+the uppermost deposits, we may conclude that the
+first outburst of volcanic action occurred towards the
+close of the Miocene period&mdash;a period remarkable for
+similar exhibitions of internal igneous action in other
+parts of the world.</p>
+
+<p>(<i>c.</i>) <i>Successive Stages of Volcanic Action in Auvergne.</i>&mdash;The
+volcanic region here described, which has an
+area of about one hundred square miles, does not
+appear to have been at one and the same period of
+time the theatre of volcanic action over its whole
+extent. On the contrary, this action appears to have
+commenced at the southern border of the region in
+the Cantal, and travelling northwards, to have broken
+out in the Mont Dore region; finally terminating its
+outward manifestations among the craters and domes
+of the Puy de Dôme. In a similar manner the volcanic
+eruptions of the Haute Loire and Ardèche,
+lying to the eastward, and separated from those of the
+Cantal by the granitoid ridge of the Montagnes de
+Margeride, belong to two successive periods referable
+very closely to those of the Mont Dore and the Puy de
+<span class="pagenum"><a name="Page_98" id="Page_98">[Pg 98]</a></span>Dôme groups.<a name="FNanchor_5_83" id="FNanchor_5_83"></a><a href="#Footnote_5_83" class="fnanchor">[5]</a> The evidence in support of this view
+is very clear and conclusive; for, while the volcanic
+craters formed of ash, lapilli, and scoriæ, together with
+the rounded domes of trachytic rock of which the
+Puy de Dôme group is composed, preserve the
+form and surface indications of recently extinguished
+volcanoes, those which we may assume to have been
+piled up in the region of Mont Dore and Cantal have
+been entirely swept away by prolonged rain and river
+action, and the sites of the ancient craters and cones
+of eruption are only to be determined by tracing the
+great sheets of lava up the sides of the valleys to their
+sources, generally situated at the culminating points
+of their respective groups. Other points of evidence
+of the great antiquity of the latter groups might be
+adduced from the extent of the erosion which has
+taken place in the sheets of lava having their sources
+in the vents of the Plomb du Cantal and of Mont Dore,
+owing to which, magnificent valleys, many miles in
+length and hundreds of feet in depth, have been cut
+out of these sheets of lava and their supporting
+rocks, whether granitic or lacustrine, and the materials
+carried away by the streams which flow along their
+beds. These points will be better understood when
+I come to give an account of the several groups;
+and in doing so I will commence with that of the
+Cantal.<a name="FNanchor_6_84" id="FNanchor_6_84"></a><a href="#Footnote_6_84" class="fnanchor">[6]</a></p>
+
+<p>(<i>d.</i>) <i>The Volcanoes of the Cantal.</i>&mdash;The original
+<span class="pagenum"><a name="Page_99" id="Page_99">[Pg 99]</a></span>crater-cones of this group have entirely disappeared
+throughout the long ages which have elapsed since the
+lava-streams issued forth from their internal reservoirs.
+The general figure of this group of volcanic mountains
+is that of a depressed cone, whose sides slope away in
+all directions from the central heights, which are
+deeply eroded by streams rising near the apex and
+flowing downwards in all directions towards the
+circumference of the mountain, where they enter the
+Lot, the Dordogne, and the Allier. The orifice of
+eruption was situated at the Plomb du Cantal, formed
+of solid masses of trachyte, which, owing, as Mr.
+Scrope supposes, to a high degree of fluidity, were
+able to extend to great distances in extensive sheets,
+and were afterwards covered by repeated and widely-spread
+flows of basalt; so that the trachyte towards
+the margin of the volcanic area becomes less conspicuous
+than the basalt by which it is more or
+less concealed from view, or overlapped. Extensive
+beds of tuff and breccia accompany the trachytic
+masses.</p>
+
+<p>Magnificent sections of the rocks are laid open to
+view along the sides of the valleys, which are steep
+and rock-bound. Except towards the south-west,
+about Aurillac, where lacustrine strata overlie the
+granite, the platform from which rises the volcanic
+dome is composed of granitic or gneissose rocks.
+Accompanying the lava-streams are great beds of
+volcanic agglomerate, which Mr. Scrope considers to
+have been formed contemporaneously with the lava
+which they envelop, and to be due to torrents of
+water tumultuously descending the sides of the
+volcano at periods of eruption, and bearing down
+immense volumes of its fragmental <i>ejecta</i> in company
+<span class="pagenum"><a name="Page_100" id="Page_100">[Pg 100]</a></span>with its lava-streams.<a name="FNanchor_7_85" id="FNanchor_7_85"></a><a href="#Footnote_7_85" class="fnanchor">[7]</a> Nowhere throughout
+this region do beds of trachyte and basalt alternate
+with one another; in all cases the basalt is the newer
+of the two varieties of rock, and this is generally the
+case throughout the region here described.</p>
+
+<p>(<i>e.</i>) <i>Volcanoes of Mont Dore.</i>&mdash;This mountain lies to
+the north of that of Cantal, and somewhat resembles
+it in general structure and configuration. Like
+Cantal, it is destitute of any distinct crater; all that is
+left of the central focus of eruption being the solidified
+matter which filled the throat of the original volcano,
+and which forms a rocky mass of lava, rising in its
+highest point, the Pic de Saucy, to an elevation (as
+given by Ramond) of 6258 feet above the level of the
+sea, thus exceeding that of the Plomb du Cantal by
+128 feet. Its figure will be best understood by
+supposing seven or eight rocky summits grouped
+together within a circle of about a mile in diameter,
+from whence, as from the apex of an irregular and
+flattened cone, all the sides slope more or less
+rapidly downwards, until their inclination is gradually
+lost in the plain around. This dome-shaped
+mass has been deeply eroded on opposite sides
+by the valleys of the Dordogne and Chambon;
+while it is further furrowed by numerous minor
+streams.<a name="FNanchor_8_86" id="FNanchor_8_86"></a><a href="#Footnote_8_86" class="fnanchor">[8]</a></p>
+
+<p>The great beds of volcanic rock, disposed as above
+stated, consist of prodigious layers of scoriæ, pumice-stones,
+and detritus, alternating with beds of trachyte
+and basalt, which often descend in uninterrupted currents
+till they reach the granite platform, and then
+spread themselves for miles around. The sheets of
+basalt are found to stretch to greater distances than
+<span class="pagenum"><a name="Page_101" id="Page_101">[Pg 101]</a></span>those of trachyte, and have flowed as far as 15 or
+20 miles from their orifices of eruption; while in
+some cases, on the east and north sides, they have extended
+as far as 25 or 30 miles from the central height.
+On the other hand, a radius of about ten miles from
+the centre would probably include all the streams of
+trachyte;&mdash;so much greater has been the viscosity of
+the basalt over the latter rock. Some portions of these
+great sheets of lava, cut off by river valleys or eroded
+areas from the main mass of which they once
+formed a part, are found forming isolated terraces and
+plateaux either on the granitic platform, or resting on
+the fresh-water strata of the valley of the Allier, while
+in a northern direction they overspread a large portion
+of the granitic plateau from which rise the Puy de
+Dôme and associated volcanic mountains. Still more
+remarkable are the cases in which these lava-streams
+have descended into the old river channels which
+drained the granitic plateau. Thus the current which
+took its origin in the Puy Gros descended into the
+valley of the Dordogne, while another stream invaded
+the gorge of Champeix on the eastern side.</p>
+
+<p>The more ancient lava-streams just described are
+invaded by currents and surmounted by cones of
+eruption of more recent date, similar to those of the
+Puy de Dôme group lying to the northward. Such
+cones and currents, amongst which are the Puy de
+Tartaret and that of Montenard, present exactly the
+same characters as those of this group, to which we
+shall return further on.</p>
+
+<p>(<i>f.</i>) <i>Volcanoes of the Haute Loire and Ardèche.</i>&mdash;Separated
+by the valley of the Allier and the granitic
+ridge of La Margeride from the volcanic regions of
+Cantal and Mont Dore is another volcanic region of
+<span class="pagenum"><a name="Page_102" id="Page_102">[Pg 102]</a></span>great extent, which reaches its highest elevation in the
+central points of Mont Mezen, attaining an elevation
+(according to Cordier) of 5820 feet, and formed of
+"clinkstone." The volcanic products of Mezen have
+been erupted from one central orifice of vast size, and
+consist mainly of extensive sheets of "clinkstone,"
+a variety of trachytic lava, which have taken courses
+mainly towards the north-west and south-east. These
+great sheets, one of which appears to have covered
+a space more than 26 miles in length with an average
+breadth of 6 miles, thus overspreading an estimated
+area of 156 square miles, has been deeply eroded by
+streams draining into the Loire, along whose banks
+the rocks tower in lofty cliffs; while it has also suffered
+enormous denudation, by which outlying fragments
+are disconnected from the main mass, and form flat-topped
+hills and plateaux as far distant as Roche en
+Reigner and Beauzac, at the extreme distance (as
+stated above) of 26 miles from the source of
+eruption.</p>
+
+<p>But even more remarkable than the above are the
+vast basaltic sheets which stretch away for a distance
+of 30 miles by Privas almost to the banks of the
+Rhône, opposite Montlimart. These have their origin
+amongst the clinkstone heights of Mont Mezen, and
+taking their course along the granitic plateau in a
+south-easterly direction, ultimately pass over on to
+the Jurassic and Cretaceous formations composing the
+plateau of the Coiron, which break off in vertical cliffs
+from 300 to 400 feet in height, surmounting the
+slopes that rise from the banks of the Ardèche and
+Escourtais rivers near Villeneuve de Bere. This is
+probably one of the most extensive sheets of basalt
+with which we are acquainted in the European area,
+<span class="pagenum"><a name="Page_103" id="Page_103">[Pg 103]</a></span>and it is only a remnant of a vastly greater original
+sheet.<a name="FNanchor_9_87" id="FNanchor_9_87"></a><a href="#Footnote_9_87" class="fnanchor">[9]</a></p>
+
+<div class="figcenter">
+<a name="FIGURE_19"></a>
+<a href="images/figure19full.jpg">
+  <img src="images/figure19.jpg" alt="Mont Demise" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 19.</span>&mdash;Mont Demise, near Le Puy, seen from the S.E. (After Scrope.)&mdash;1. Building standing on old breccia, rocks of
+the Col; 2. Road to Brioude; 3. Croix de la Paille; 4. Orgue d'Expailly (basalt); 5. Spot where human bones were found.
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_104" id="Page_104">[Pg 104]</a></span></p><p>(<i>g.</i>) <i>Newer Volcanoes of the Haute Loire (the Velay
+and Vivarais).</i>&mdash;Subsequently to the formation of the
+lava-streams above described, and probably after the
+lapse of a lengthened period, the region of the Haute
+Loire and Ardèche became the scene of a fresh outburst
+of volcanic action, during which the surface of
+the older lavas, or of the fundamental granite, was
+covered by numerous crater-cones and lava-streams
+strewn along the banks of the Allier and of the Loire
+for many miles. These cones and craters are not
+quite so fresh as those of the Mont Dôme group;
+those of the Haute Loire being slightly earlier in
+point of time, and, as Daubeny shows, belonging
+to a different system. So numerous are these more
+recent cones and craters that Scrope counted more
+than 150 of them, and probably omitted many.</p>
+
+<p>The volcanic phenomena now described have a
+special interest as bearing on the question whether
+man was an inhabitant of this region at the time of
+these later eruptions. The question seems to be
+answered in the affirmative by the discovery of a
+human skull and several bones in the volcanic breccia
+of Mont Demise, in company with remains of the
+elephant (<i>E. primigenius</i>), rhinoceros (<i>R. tichorhinus</i>),
+stag, and other large mammifers. The discovery of
+these remains was made in the year 1844, and the
+circumstances were fully investigated and reported
+upon by M. Aymard, and afterwards by Mr. Poulett
+Scrope, upon whose mind no possible doubt of the
+<span class="pagenum"><a name="Page_105" id="Page_105">[Pg 105]</a></span>fact remained. From what we now know of the
+occurrence of human remains and works of art in
+other parts of France and Europe, no surprise need
+be felt at the occurrence of human remains in company
+with some extinct mammalia in these volcanic
+tuffs, which belong to the Post-Pliocene or superficial
+alluvia antecedent to the historic period.<a name="FNanchor_10_88" id="FNanchor_10_88"></a><a href="#Footnote_10_88" class="fnanchor">[10]</a></p>
+
+<p>(<i>h.</i>) <i>Mont Dôme Chain.</i>&mdash;We now come to the
+consideration of the most recent of all the volcanic
+mountain groups of the region of Central France, that
+of the Puy de Dôme, lying to the north of Mont Dore
+and Cantal. We have seen that there is almost conclusive
+evidence that man was a witness to the later
+volcanic outbursts of the Vivarais, and as these craters
+seem to be of somewhat earlier date than those of the
+Puy de Dôme group, we cannot doubt that they were
+in active eruption when human beings inhabited the
+country, and not improbably within what is known
+as the <i>Historic Period</i>. No mention, however, is made
+either by Cæsar, Pliny, or other Roman writers of the
+existence of active volcanoes in this region. Cæsar,
+who was a close observer, and who carried the Roman
+arms into Auvergne, makes no mention of such; nor
+yet does the elder Pliny, who enumerated the known
+burning mountains of his day all over the Roman
+<span class="pagenum"><a name="Page_106" id="Page_106">[Pg 106]</a></span>Empire. It is not till we come down to the fifth
+century of our era that we find any notices which
+might lead us to infer the existence of volcanic action
+in Central France. This is the well-known letter
+written by Sidonius Apollonarius, bishop of Auvergne,
+to Alcinus Avitus, bishop of Vienne, in which the
+former refers to certain terrific terrestrial manifestations
+which had occurred in the diocese of the latter.
+But, as Dr. Daubeny observes, this is no evidence of
+volcanic action in Auvergne, where Sidonius himself
+resided; the terrestrial disturbances above referred
+to may have been earthquake shocks of extreme
+severity.<a name="FNanchor_11_89" id="FNanchor_11_89"></a><a href="#Footnote_11_89" class="fnanchor">[11]</a></p>
+
+<p>But although we have no reliably historical record
+of volcanic action amongst the mountains of the Mont
+Dôme group, the fact that these are, comparatively,
+extremely recent will be evident to an observer visiting
+this district, and this conclusion is based on three
+principal grounds: first, because of the well-preserved
+forms of the original craters, though generally composed
+of very loose material, such as ashes, lapilli, and
+slag; secondly, because of the freshness of the lava-streams
+over whose rugged surfaces even a scanty
+herbage has in some places scarcely found a footing;<a name="FNanchor_12_90" id="FNanchor_12_90"></a><a href="#Footnote_12_90" class="fnanchor">[12]</a>
+and thirdly, because the lava from the crater-cones has
+invaded channels previously occupied by the earlier
+lavas, or those which had been eroded since the
+overflow of the great basaltic sheets of Mont Dore.
+Still, as in the case of the valleys of Lake Aidot, of
+Channonat, and of Royat, these streams are sufficiently
+<span class="pagenum"><a name="Page_107" id="Page_107">[Pg 107]</a></span>ancient to have given time for the existing rivers to
+have worn out in them channels of some depth, but
+bearing no comparison to the great valleys which had
+been eroded out of the more ancient lavas, such as
+those of the Coiron, of the Ardèche, and of the
+Dordogne and Chambon in the district of Mont Dore.</p>
+
+<p>(<i>i.</i>) <i>Dome-shaped Volcanic Hills.</i>&mdash;I have previously
+(<a href="#Page_15">page 15</a>) referred to the two classes of volcanic eminences
+to be found in the chain of the Puy de Dôme;
+one indicated by the name itself, formed of a variety
+of trachytic lava called "domite," and of the form of a
+dome; the other, composed of fragmental matter piled
+up in the form of a crater or cup, often ruptured on
+one side by a stream of lava which has burst through
+the side, owing to its superior density. Of the former
+class the Puy de Dôme and the Grand Sarcoui (see
+<a href="#FIGURE_18">Fig. 18</a>) are the most striking examples out of the
+five enumerated by Scrope, while there is a large
+number, altogether sixty-one, belonging to the latter
+class. These domes and crater-cones, as already
+stated, rise from a platform of granite, either directly
+or from one formed of the lava-sheets of the Mont
+Dore region, which in turn overlies the granitic platform.
+Of the nearly perfect craters there are the
+Petit Puy de Dôme, lying partially against the
+northern flank of the greater eminence; the Puy de
+Cone, remarkable for the symmetry of its conical
+form, rising to a height of 900 feet from the plain;
+and the Puys de Chaumont and Thiolet lying to the
+north of the Puy de Dôme. Of those to the south of
+this mount, two out of the three craters of the Puy de
+Barme and the Puy de Vichatel are perfect; but most
+of the crater-cones south of the Puy de Dôme are
+breached. Some of the lava streams by which these
+<span class="pagenum"><a name="Page_108" id="Page_108">[Pg 108]</a></span>craters were broken down flowed for long distances.
+That the lava followed the showers of ashes and lapilli
+forming the walls of the craters is rendered very evident
+in the case of the Puy de la Vache, whose lava-stream
+coalescing with those from the Puy de la Solas and
+Puy Noir, deluged the surrounding tracts and flowed
+down the Channonat Valley as far as La Roche
+Blanc in the Vale of Clermont. In the interior of
+the upper part of the crater still remaining may be
+seen the level (so to speak) to which the molten lava
+rose before it burst its barrier. This level is marked
+by a projecting platform of reddish or yellow material,
+rich in specular iron, apparently part of the frothy
+scum which formed on the surface of the lava and
+adhered to the side of the basin at the moment of its
+being emptied.</p>
+
+<p>Space does not permit a fuller description of this
+remarkable assemblage of extinct volcanoes, and the
+reader must be referred for further details to the work
+of Mr. Scrope. I shall content myself with some
+further reference to the central figure in this grand
+chain, the Puy de Dôme itself.</p>
+
+<p><i>Ascent of the Puy de Dôme.</i>&mdash;On ascending by the
+winding path up the steep side of the mount, and on
+reaching the somewhat flattened summit, the first
+objects which strike the eye are the massive foundations
+of the Roman temple of Mercury; they are hewn
+out of solid grey lava, altogether different from the
+rock of the Puy de Dôme itself, which must have been
+obtained from one of the lava-sheets of the Mont
+Dore group. To have carried these large blocks to
+their present resting-place must have cost no little
+labour and effort. The temple is supposed to have
+been surmounted by a colossal statue of the winged
+<span class="pagenum"><a name="Page_109" id="Page_109">[Pg 109]</a></span>deity, visible from all parts of the surrounding
+country which was dedicated to his honour, and the
+foundations were only discovered a few years ago
+when excavating for the foundation of the observatory,
+which stands a little further on under the charge
+of Professor Janssen. On proceeding to the northern
+crest of the platform a wonderful view of the extinct
+craters and domes&mdash;about forty in number, and terminating
+in the Puy de Beauny, the most northerly
+member of the chain&mdash;is presented to the spectator.
+To the right is the Vale of Clermont and the rich valley
+of the Allier merging into the great plain of Central
+France. On the south side of the platform a no less
+remarkable spectacle meets the eye. The chain of
+Puys and broken craters stretches away southwards
+for a distance of nearly ten miles, while the horizon is
+bounded in that direction by the lofty masses of the
+Mont Dore, Cantal, and Le Puy ranges. Nor does
+it require much effort of the imagination to restore
+the character of the region when these now dormant
+volcanoes were in full activity, projecting showers of
+ashes and stones high into the air amidst flames of
+fire and vast clouds of incandescent gas and steam.</p>
+
+<p>The material of which the Puy de Dôme is formed
+consists of a light grey, nearly white, soft felsitic
+lava, containing crystals of mica, hornblende, and
+specular iron-ore. It is highly vesicular, and was
+probably extruded in a pasty condition from a throat
+piercing the granitic plateau and the overlying sheet
+of ancient lava of Mont Dore. It has been suggested
+that such highly felsitic and acid lavas as that of
+which the Puy de Dôme, the Grand Sarcoui, and
+Cliersou are composed, may have had their origin
+in the granite itself, melted and rendered viscous by
+<span class="pagenum"><a name="Page_110" id="Page_110">[Pg 110]</a></span>intense heat. Dr. E. Gordon Hull has suggested
+that the domite hills (owing to their low specific
+gravity) may have filled up pre-existing craters
+of ashes and scoriæ without rupturing them, as
+in the case of the heavier basaltic lavas, and then
+still continuing to be extruded, may have entirely
+enveloped them in its mass; so that each domite
+hill encloses within its interior a crater formed of
+ashes, stones, and scoriæ. In the case of the Puy
+de Dôme there is some evidence that the domite
+matter rests on a basis of ashes and scoriæ, which
+may be seen in a few places around the base of the
+cone. It is difficult without some such theory as
+this to explain how a viscous mass was able to
+raise mountains some 2000 or 3000 feet above the
+surrounding plain.<a name="FNanchor_13_91" id="FNanchor_13_91"></a><a href="#Footnote_13_91" class="fnanchor">[13]</a></p>
+
+<p>(<i>j.</i>) <i>Sketch of the Volcanic History of Central
+France.</i>&mdash;It now only remains to give a brief <i>resumé</i>
+of the volcanic history of this region as it may be
+gathered from the relations of the rocks and strata
+to the volcanic products, and of these latter to each
+other.</p>
+
+<p><i>1st Stage.</i>&mdash;It would appear that at the close of
+the Eocene period great terrestrial changes occurred.
+The bed of the sea was converted into dry land, the
+strata were flexured and denuded, and a depression
+was formed in the granitic floor of Central France,
+which, in the succeeding Miocene period, was converted
+into an extensive lake peopled by molluscs,
+fishes, reptiles, and pachyderms of the period.</p>
+
+<p><span class="pagenum"><a name="Page_111" id="Page_111">[Pg 111]</a></span></p><p><i>2nd Stage.</i>&mdash;Towards the close of the Miocene
+epoch volcanic eruptions commenced on a grand
+scale over the granitic platform in the districts now
+called Mont Dore, Cantal, and the Vivarais. Vast
+sheets of trachytic and basaltic lavas successively
+invaded the tracts surrounding the central orifices of
+eruption, now constituting the more ancient of the
+lava-sheets of the Auvergne region, and, invading
+the waters of the neighbouring lake, overspread the
+lacustrine deposits which were being accumulated
+therein. These volcanic eruptions probably continued
+throughout the Pliocene period, interrupted
+by occasional intervals of inactivity, and ultimately
+altogether ceased.</p>
+
+<p><i>3rd Stage.</i>&mdash;Towards the close of the Pliocene
+period terrestrial movements took place, owing to
+which the waters of the lake began to fall away, and
+the sheets of lava were subjected to great denudation.
+This process, probably accelerated by excessive rainfall
+during the succeeding Post-Pliocene and Pluvial
+periods, was continued until plains and extensive
+river-valleys were eroded out of the sheets of lava and
+their supporting granitic rocks and the adjoining
+lacustrine strata.</p>
+
+<p><i>4th Stage.</i>&mdash;A new outburst of volcanic forces
+marks this stage, during which the chain of the Puy
+de Dôme was thrown up on the west, and that of the
+newer cones of the Vivarais on the south-east of the
+lacustrine tract. The waters of the lake were now
+completely drained away through the channel of the
+Allier, and denudation, extending down to the
+present day, began over the area now forming the
+Vale of Clermont and adjoining districts. The volcanic
+action ultimately spent its force; and somewhere
+<span class="pagenum"><a name="Page_112" id="Page_112">[Pg 112]</a></span>about the time of the appearance of man, the mammoth,
+rhinoceros, stag, and reindeer on the scene,
+eruptions entirely ceased, and gradually the region
+assumed those conditions of repose by which it is
+now physically characterised.</p>
+
+<div class="footnote"><p><a name="Footnote_1_79" id="Footnote_1_79"></a><a href="#FNanchor_1_79"><span class="label">[1]</span></a> The literature referring to this region is very extensive. Guettard
+in 1775, afterwards Faujas, published descriptions of the rocks of the
+Vivarais and Velay; and Desmarest's geological map, published in
+1779, is a work of great merit. The district was afterwards described
+by Daubeny, Lyell, Von Buch, and others; but by far the most
+complete work is that of Scrope, entitled <i>Volcanoes of Central France</i>,
+containing maps and numerous illustrations, published in 1826, and
+republished in a more extended form in 1858; to this I am largely
+indebted.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_80" id="Footnote_2_80"></a><a href="#FNanchor_2_80"><span class="label">[2]</span></a> A monument to Pascal, erected by the citizens, occupies the centre
+of the square in Clermont. It will be remembered that Pascal verified
+the conclusions arrived at by Torricelli regarding the pressure of the
+atmosphere, by carrying a Torricellian tube to the summit of the
+Puy de Dôme, and recording how the mercury continually fell during
+the ascent, and rose as he descended. This experiment was made in
+1645.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_81" id="Footnote_3_81"></a><a href="#FNanchor_3_81"><span class="label">[3]</span></a> In this visit to Auvergne in the summer of 1880, the author was
+accompanied by his son, Dr. E. Gordon Hull, and Sir Robert S. Ball.
+On reaching the station at the summit of the ridge it seemed as if
+the volcanic fires had again been lighted, for the whole sky was aglow
+with the rays of the western sun.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_82" id="Footnote_4_82"></a><a href="#FNanchor_4_82"><span class="label">[4]</span></a> On the other hand, certain beds of ash and other volcanic <i>ejecta</i>
+occur in <i>the uppermost</i> strata of lake deposits of Limagne, so that these
+may indicate the commencement of the period of eruption, as suggested
+further on.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_83" id="Footnote_5_83"></a><a href="#FNanchor_5_83"><span class="label">[5]</span></a> Only very closely; for Mr. Scrope considers that the crater-cones
+of the chain of the Haute Loire give evidence of a somewhat earlier
+epoch of activity than those of the Puy de Dôme, as they have undergone
+a greater amount of subaerial erosion.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_84" id="Footnote_6_84"></a><a href="#FNanchor_6_84"><span class="label">[6]</span></a> The extent of this river erosion has been clearly brought out by
+Scrope, and is admirably illustrated by several of his panoramic views,
+such as that in Plate IX. of his work.</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_85" id="Footnote_7_85"></a><a href="#FNanchor_7_85"><span class="label">[7]</span></a> Scrope, <i>loc. cit.</i>, p. 147.</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_86" id="Footnote_8_86"></a><a href="#FNanchor_8_86"><span class="label">[8]</span></a> Scrope, <i>loc. cit.</i>, p. 144.</p></div>
+
+<div class="footnote"><p><a name="Footnote_9_87" id="Footnote_9_87"></a><a href="#FNanchor_9_87"><span class="label">[9]</span></a> Scrope gives a view of these remarkable basaltic cliffs in Plate
+XII. of his work, from which the above account is taken. At one spot
+near the village of Le Gua there is a break in the continuity of the sheet.</p></div>
+
+<div class="footnote"><p><a name="Footnote_10_88" id="Footnote_10_88"></a><a href="#FNanchor_10_88"><span class="label">[10]</span></a> See Scrope, <i>loc. cit.</i>, p. 181; also Appendix, <a href="#Page_228">p. 228</a>. While there
+is no <i>primâ facie</i> reason for questioning the origin of the Demise skull,
+yet from what Lyell states in his <i>Antiquity of Man</i>, p. 196, it will be
+seen that he found it impossible to identify its position, or to determine
+beyond question that its interment was due to natural causes. But
+assuming this to be the case, he shows how the individual to whom it
+belonged might have been enveloped in volcanic tuff or mud showered
+down during the final eruption of the volcano of Demise. MM.
+Hébert and Lartet, on visiting the locality, also failed to find <i>in situ</i> any
+exact counterpart of the stone now in the museum of Le Puy.</p></div>
+
+<div class="footnote"><p><a name="Footnote_11_89" id="Footnote_11_89"></a><a href="#FNanchor_11_89"><span class="label">[11]</span></a> See Daubeny, <i>Volcanoes</i>, p. 31.</p></div>
+
+<div class="footnote"><p><a name="Footnote_12_90" id="Footnote_12_90"></a><a href="#FNanchor_12_90"><span class="label">[12]</span></a> That is to say, the surfaces of the lava-streams are not at all, or
+only slightly, decomposed into soil suitable for the growth of plants,
+except in rare instances.</p></div>
+
+<div class="footnote"><p><a name="Footnote_13_91" id="Footnote_13_91"></a><a href="#FNanchor_13_91"><span class="label">[13]</span></a> E. G. Hull, "On the Domite Mountains of Central France,"
+<i>Scien. Proc. Roy. Dublin Society</i>, July 1881, p. 145. Dr. Hull determined
+the density of the domite of the Puy de Dôme to be 2.5, while
+that of lava is about 3.0.</p></div>
+<p><span class="pagenum"><a name="Page_113" id="Page_113">[Pg 113]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_II_CHAPTER_VII" id="PART_II_CHAPTER_VII"></a>CHAPTER VII.
+<br /><br />
+THE VOLCANIC DISTRICT OF THE RHINE VALLEY.</h2>
+
+
+<p>The region bordering the Rhine along both its
+banks above Bonn, and extending thence along the
+valley of the Moselle and into the Eifel, has been
+the theatre of active volcanic phenomena down into
+recent times, but at the present day the volcanoes are
+dormant or extinct.</p>
+
+<p>(<i>a.</i>) <i>Geological Structure.</i>&mdash;The fundamental rocks
+of this region belong to the Silurian, Devonian, and
+Carboniferous systems, consisting of schists, grits, and
+limestones, with occasional horizontal beds of Miocene
+sandstone and shale with lignite, resting on the
+upturned edges of the older rocks. Scattered over
+the greater part of the district here referred to are a
+number of conical eminences, often with craters, the
+bottoms of which are usually sunk much below the
+present level of the country, and thus receiving the
+surface drainage, have been converted into little
+lakes called "maars," differing from ordinary lakes by
+their circular form and the absence of any <i>apparent</i>
+outlet for their waters.<a name="FNanchor_1_92" id="FNanchor_1_92"></a><a href="#Footnote_1_92" class="fnanchor">[1]</a></p>
+
+<p><span class="pagenum"><a name="Page_114" id="Page_114">[Pg 114]</a></span></p><p>But before entering into details, it may be desirable
+to present the reader with a short outline of the
+physical history of the region (which has been
+ably done by Dr. Hibbert in his treatise, to which I
+have already referred), so as to enable him better to
+understand the succession of physical events in its
+volcanic history.</p>
+
+<div class="figcenter">
+<a name="FIGURE_20">
+  <img src="images/figure20.jpg" alt="Rhenish area" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 20.</span>&mdash;Sketch Map to show the physical condition of the Rhenish
+area in the Miocene epoch.&mdash;(After Hibbert.)
+</td></tr>
+</table>
+</div>
+
+<p>(<i>b.</i>) <i>Physical History.</i>&mdash;From the wide distribution
+of stratified deposits of sand and clay at high levels
+on both banks of the Rhine north of the Moselle,
+it would appear that an extensive fresh-water basin,
+which Dr. Hibbert calls "The Basin of Neuwied,"
+occupied a considerable tract on both banks, in the
+centre of which the present city of Neuwied stands.
+This basin was bounded towards the south by the
+slopes of the Hündsruck and Taunus, which at the
+<span class="pagenum"><a name="Page_115" id="Page_115">[Pg 115]</a></span>time here referred to formed a continuous chain of
+mountains. (<a href="#FIGURE_20">Fig. 20</a>.) To the south of this chain
+lay the Tertiary basin of Mayence, which was connected
+at an early period&mdash;that of the Miocene&mdash;with
+the waters of the ocean, as shown by the fact that the
+lower strata contain marine shells; these afterwards
+gave place to fresh-water conditions. The basin of
+Neuwied was bounded towards the north by a ridge of
+Devonian strata which extended across the present
+gorge of the Rhine between Andernach and Linz,
+and to the north of this barrier lay another more
+extensive fresh-water basin, that of Cologne. From
+this it will be seen that the Rhine, as we now find
+it, had then only an infantile existence; in fact, its
+waters to the south of the Hündsruck ridge drained
+away towards the south. But towards the commencement
+of the Pliocene period the barriers of the
+Hündsruck and Taunus, as also that of the Linz, were
+broken through, and the course of the waters was
+changed; and thus gradually, as the river deepened its
+bed, the waters were drained off from the great lakes.<a name="FNanchor_2_93" id="FNanchor_2_93"></a><a href="#Footnote_2_93" class="fnanchor">[2]</a>
+This rupture of the barriers may have been due,
+in the first instance, to the terrestrial disturbances
+accompanying the volcanic eruptions of the Eifel and
+Siebengebirge, though the erosion of the gorges at
+Bingen and at Linz to their present depth and
+dimensions is of course due to prolonged river action.
+It was about the epoch we have now arrived at&mdash;viz.,
+the close of the Miocene&mdash;that volcanic action
+burst forth in the region of the Lower Rhine. It is
+probable that this action commenced in the district
+<span class="pagenum"><a name="Page_116" id="Page_116">[Pg 116]</a></span>of the Siebengebirge, and afterwards extended into
+that of the Moselle and the Eifel, the volcanoes of
+which bear evidence of recent date. Layers of trachytic
+tuff are interstratified with the deposits of sand, clay,
+and lignite of the formation known as that of the
+Brown Coal&mdash;of Miocene age&mdash;which underlies nearly
+the whole of the volcanic district on both sides of the
+Rhine near Bonn,<a name="FNanchor_3_94" id="FNanchor_3_94"></a><a href="#Footnote_3_94" class="fnanchor">[3]</a> thus showing that volcanic action
+had already commenced in that part to some extent;
+but it does not appear from Dr. Hibbert's statement
+that any such fragments of eruptive rock are to be
+found in the strata which were deposited over the
+floor of the Neuwied basin.<a name="FNanchor_4_95" id="FNanchor_4_95"></a><a href="#Footnote_4_95" class="fnanchor">[4]</a> It will be recollected
+that the epoch assigned for the earliest volcanic eruptions
+of Auvergne was that here inferred for those of the
+Lower Rhine&mdash;viz., the close of the Miocene stage&mdash;and
+from evidence subsequently to be adduced from
+other European districts, it will be found that there
+was a very widely spread outburst of volcanic action
+at this epoch.</p>
+
+<p>(<i>c.</i>) <i>The Range of the Siebengebirge.</i>&mdash;This range
+of hills&mdash;formed of the older volcanic rocks of the
+Lower Rhine&mdash;rises along the right bank of this
+noble river opposite Bonn, where it leaves the narrow
+gorge which it traverses all the way from Bingen, and
+opens out on the broad plain of Northern Germany.
+The range consists of a succession of conical hills sometimes
+flat-topped&mdash;as in the case of Petersberg; and at
+the Drachenfels, near the centre of the range it presents
+to the river a bold front of precipitous cliffs of trachyte
+<span class="pagenum"><a name="Page_117" id="Page_117">[Pg 117]</a></span>porphyry. The sketch (<a href="#FIGURE_21">Fig. 21</a>) here presented was
+taken by the author in 1857 from the old extinct volcano
+of Roderberg, and will convey, perhaps, a better
+idea of the character of this picturesque range than a
+description. The Siebengebirge, although appearing
+as an isolated group of hills, is in reality an offshoot
+from the range of the Westerwald, which is connected
+with another volcanic district of Central
+Germany known as the Vogelsgebirge. The highest
+point in the range is attained in the Lohrberg, which
+rises 1355 feet above the sea; the next, the Great
+Tränkeberg, 1330 feet; and the next, Great Oelberg,
+1296 feet.</p>
+
+<div class="figcenter">
+<a name="FIGURE_21">
+  <img src="images/figure21.jpg" alt="Range of the Siebengebirge" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 21.</span>&mdash;The Volcanic Range of the Siebengebirge, seen from the left bank of the Rhine, above Bonn.&mdash;(Original.)
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_118" id="Page_118">[Pg 118]</a></span></p><p>The range consists mainly of trachytic rocks&mdash;namely,
+trachyte-conglomerate, and solid trachyte,
+of which H. von Dechen makes two varieties&mdash;that
+of the Drachenfels, and that of the Wolkenburg. But
+associated with these highly-silicated varieties of lava&mdash;and
+generally, if not always, of later date&mdash;are basaltic
+rocks which cap the hills of Petersberg, Nonnenstrom,
+Gr. and Ll. Oelberg, Gr. Weilberg, and Ober
+Dollendorfer Hardt. The question whether there is a
+transition from the one variety of volcanic rock into
+the other, or whether each belongs to a distinct and
+separate epoch of eruption, does not seem to be very
+clearly determined. Mr. Leonard Horner states that
+it would be easy to form a suite of specimens showing
+a gradation from a white trachyte to a black basalt;<a name="FNanchor_5_96" id="FNanchor_5_96"></a><a href="#Footnote_5_96" class="fnanchor">[5]</a>
+but we must recollect that when Mr. Horner wrote,
+the microscopic examination of rocks by means of
+thin sections was not known or practised, and an
+examination by this process might have proved that
+this apparent transition is unreal. According to H.
+<span class="pagenum"><a name="Page_119" id="Page_119">[Pg 119]</a></span>von Dechen, there are sheets of basalt older than the
+greater mass of the brown coal formation, and others
+newer than the trachyte;<a name="FNanchor_6_97" id="FNanchor_6_97"></a><a href="#Footnote_6_97" class="fnanchor">[6]</a> while dykes of basalt
+traversing the trachytic lavas are not uncommon.<a name="FNanchor_7_98" id="FNanchor_7_98"></a><a href="#Footnote_7_98" class="fnanchor">[7]</a></p>
+
+<p>The trachyte-conglomerate&mdash;which seems to be
+associated with the upper beds of the brown coal strata&mdash;is
+traversed by dykes of trachyte of later date; and
+though it is difficult to trace the line between the two
+varieties of this rock on the ground, Dr. von Rath
+has recognised the general distinction between them,
+which consists in the greater abundance of hornblende
+and mica in the trachyte of the Wolkenburg than in
+that of the Drachenfels.</p>
+
+<p>The trachyte of the Drachenfels was probably the
+neck of a volcano which burst through the fundamental
+schists of the Devonian period. It is remarkable
+for the large crystals of sanidine (glassy felspar)
+which it contains, and has a rude columnar structure.</p>
+
+<p>The absence of any clearly-defined craters of
+eruption, such as are to be found in the Eifel district
+and on the left bank of the Rhine&mdash;as, for example,
+in the case of the Roderberg&mdash;may be regarded as
+sufficient evidence that this range is of comparatively
+high antiquity. It seems to bear the same relation to
+the more modern craters of the Eifel and Moselle that
+the Mont Dore and Cantal volcanoes do to those of
+the Puy de Dôme. In both cases, denudation carried
+on throughout perhaps the Pliocene and Post-Pliocene
+periods down to the present day has had the effect
+of demolishing the original craters; so that what we
+now observe as forming these ranges are the consolidated
+<span class="pagenum"><a name="Page_120" id="Page_120">[Pg 120]</a></span>columns of original molten matter which
+filled the throats of the old volcanoes, or the sheets of
+lava which were extruded from them, but are now
+probably much reduced in size and extent.</p>
+
+<p>Having thus given a description of the older
+volcanic range on the right bank of the Rhine, we
+shall cross the river in search of some details regarding
+the more recent group of Rhenish volcanoes, commencing
+with that of the Roderberg, a remarkable
+hill a few miles south of Bonn, from which the view
+of the Seven Mountains was taken.</p>
+
+<div class="figcenter">
+<a name="FIGURE_22">
+  <img src="images/figure22.jpg" alt="Crater of the Roderberg" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 22.</span>&mdash;Section of the extinct crater of the Roderberg on the
+bank of the Rhine, above Bonn.&mdash;(Original.)
+</td></tr>
+</table>
+</div>
+
+<p>(<i>d.</i>) <i>The Roderberg.</i>&mdash;This crater, which was visited
+by the author in 1857, is about one-fourth of a mile
+in diameter, and is in the form of a cup with
+gentle slopes on all sides. In its centre is a farmhouse
+surrounded by corn-fields. The general section
+through the hill is represented above (<a href="#FIGURE_22">Fig. 22</a>).</p>
+
+<p>The flanks on the north side are composed of loose
+quartzose gravel (gerolle), a remnant of the deposits
+formed around the margin of the "Basin of Neuwied"
+described above (<a href="#Page_114">p. 114</a>). This gravel is found covering
+the terraces of the brown coal formation several
+hundred feet above the Rhine. Besides quartz-pebbles,
+the deposit contains others of slate, grit, and
+volcanic rock. On reaching the edge of the crater
+we find the gravel covered over by black and purple
+scoria or slag the superposition of the scoria on the
+<span class="pagenum"><a name="Page_121" id="Page_121">[Pg 121]</a></span>gravel being visible in several places, showing that
+the former is of more recent origin. On the opposite
+side of the crater, overlooking the Rhine, we find the
+cliff of Rolandsec composed of hard vesicular lava,
+rudely prismatic, and extending from the summit of
+the hill to its base, about 250 feet below. This is the
+most northerly of the group of the Eifel volcanoes.</p>
+
+<p>(<i>e.</i>) <i>District of the Rivers Brühl and Nette.</i>&mdash;The
+volcanic region of the Lower Eifel, drained by these
+two principal streams which flow into the Rhine, will
+amply repay exploration by the student of volcanic
+phenomena, owing to the variety of forms and conditions
+under which these present themselves within
+a small space. The fundamental rock is slate or grit
+of Devonian age, furrowed by numerous valleys, often
+richly wooded, and diversified by conical hills of
+trachyte; or by crater-cones, formed of basalt or ashes,
+sometimes ruptured on one side, and occasionally sending
+forth streams of lava, as in the cases of the Perlinkopf,
+the Bausenberg, and the Engelerkopf. The
+district attains its greatest altitude in the High Acht
+(Der Hohe Acht), an isolated cone of slate capped
+by basalt with olivine, and reaching a level of 2434
+Rhenish feet.<a name="FNanchor_8_99" id="FNanchor_8_99"></a><a href="#Footnote_8_99" class="fnanchor">[8]</a></p>
+
+<p>(<i>f.</i>) <i>The Laacher See.</i>&mdash;It would be impossible in
+a work of this kind to attempt a detailed description
+of the Eifel volcanoes, often of a very complex
+character and obscure physical history, as in the case
+of the basin of Rieden, where tufaceous deposits,
+trachytic and basaltic lavas and crater-cones, are
+confusedly intermingled, so that I shall confine my
+<span class="pagenum"><a name="Page_122" id="Page_122">[Pg 122]</a></span>remarks to the deservedly famous district of the
+Laacher See, which I had an opportunity of personally
+visiting some years since.<a name="FNanchor_9_100" id="FNanchor_9_100"></a><a href="#Footnote_9_100" class="fnanchor">[9]</a></p>
+
+<div class="figcenter">
+<a name="FIGURE_23">
+  <img src="images/figure23.jpg" alt="Laacher See" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 23.</span>&mdash;Plan and Section of the Laacher See, a lake on the
+borders of the Eifel, occupying the crater of an old volcano.&mdash;G. Gravel
+and volcanic sand forming banks of the lake and rim of old crater;
+L. Sheet of trachytic lava with columnar structure; B. Basaltic dyke;
+S. Devonian slate, etc.
+</td></tr>
+</table>
+</div>
+
+<p>The Laacher See is a lake of an oval form, over
+an English mile in the shorter diameter, and surrounded
+by high banks of volcanic sand, gravel, and
+scoriæ, except on the east side, where cliffs of clay-slate,
+in a nearly vertical position, and striking nearly
+E.W., may be observed. Its depth from the surface
+of the water is 214 feet.<a name="FNanchor_10_101" id="FNanchor_10_101"></a><a href="#Footnote_10_101" class="fnanchor">[10]</a> The ashes of the encircling
+<span class="pagenum"><a name="Page_123" id="Page_123">[Pg 123]</a></span>banks contain blocks of slate and lava which have
+been torn from the sides of the orifice or neck of the
+volcano and blown into the air; and there can be no
+doubt that the ashes and volcanic gravel is the result
+of very recent eruptions.</p>
+
+<p>At the east side of the lake we find a stream of
+scoriaceous lava of a purple or reddish colour, highly
+vesicular, and containing crystals of mica; but the
+most important lava-stream is that which has taken
+a southerly direction from the crater of the Laacher
+See towards Nieder Mendig and Mayen, for a distance
+of about six miles. This great stream is covered
+throughout half its distance by beds of volcanic ash
+and lapilli, but emerges into the air at a distance of
+about two miles from the edge of the crater (see <a href="#FIGURE_23">Fig.
+23</a>), and was formerly extensively quarried in underground
+caverns for millstones. Here the rock is a
+vesicular trachyte, of a greyish colour, solidified in
+vertical columns of hexagonal form, about four feet in
+diameter, and traversed by transverse joint planes.
+These quarries have been worked from the time of the
+Roman occupation of the country; and, before the
+introduction of iron or steel rollers for grinding corn,
+millstones were exported to all parts of Europe and
+the British Isles from this quarry.<a name="FNanchor_11_102" id="FNanchor_11_102"></a><a href="#Footnote_11_102" class="fnanchor">[11]</a></p>
+
+<p>The district around the Laacher See is covered by
+laminated <i>ejecta</i> of the old volcano, probably of subaërial
+origin, through which bosses of the fundamental
+slate peer up at intervals, while the surface is diversified
+by several truncated cones.</p>
+
+<p>(<i>g.</i>) <i>Trass of the Brühl Valley.</i>&mdash;The Brühl Valley,
+<span class="pagenum"><a name="Page_124" id="Page_124">[Pg 124]</a></span>which unites with that of the Rhine at the town of
+that name, and drains the northern side of the volcanic
+region, has always been regarded with much
+interest by travellers for the presence of a deposit of
+"trass" with which it is partially filled. The origin of
+this valley was pre-volcanic, as it is hewn out of the
+slaty rocks of the district. But at a later period it
+became filled with volcanic mud (tuffstein), out of
+which the stream has made for itself a fresh channel.
+The source of this mud is considered by Hibbert<a name="FNanchor_12_103" id="FNanchor_12_103"></a><a href="#Footnote_12_103" class="fnanchor">[12]</a>
+to have been the old volcano of the Lummerfeld,
+which, after becoming dormant, was filled with water,
+and thus became a lake. At a subsequent period,
+however, a fresh eruption took place near the edge of
+the lake, resulting in the remarkable ruptured crater
+known as the Kunksköpfe, which rises about four
+miles to the north of the Laacher See. The eruptions
+of this volcano appear to have displaced the mud of
+the Lummerfeld, causing it to flow down into the
+deep gorge of the Brühl, which it completely filled, as
+stated above.</p>
+
+<p>On walking down the valley one may sometimes
+see the junction of the tuff with the slate-rock which
+enfolds it. The tuff consists of white felspathic mud,
+with fragments of slate and lava, reaching a depth in
+some places of 150 feet. After it has been quarried
+it is ground in mills, and used for cement stone under
+the name of <i>trass</i>. It is said to resemble the volcanic
+mud by which Herculaneum was overwhelmed during
+the first eruption of Vesuvius, and which was produced
+by the torrents of rain mixing with the ashes
+as they were blown out of the volcano.</p>
+
+<p>Sufficient has probably now been written regarding
+<span class="pagenum"><a name="Page_125" id="Page_125">[Pg 125]</a></span>the dormant, or recently extinct, volcanic districts of
+Europe to give the reader a clear idea regarding
+their nature and physical structure. Other districts
+might be added, such as those of Central Germany,
+Hungary, Transylvania, and Styria; but to do so
+would be to exceed the proposed limits of this work;
+and we may therefore pass on to the consideration
+of the volcanic region of Syria and Palestine,
+which adjoins the Mediterranean district we have
+considered in a former page.</p>
+
+<div class="footnote"><p><a name="Footnote_1_92" id="Footnote_1_92"></a><a href="#FNanchor_1_92"><span class="label">[1]</span></a> Daubeny, <i>loc. cit.</i>, p. 71. The geology of this region has had
+many investigators, of whom the chief are Steininger, <i>Erloschenen
+Vulkane in der Eifel</i> (1820); Hibbert, <i>Extinct Volcanoes of the Basin
+of Neuwied</i>, 1832; Nöggerath, <i>Das Gebirge im Rheinland</i>, etc., 4 vols.;
+Horner, "On the Geology of Bonn," <i>Transactions of the Geological
+Society, London</i>, vol. iv.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_93" id="Footnote_2_93"></a><a href="#FNanchor_2_93"><span class="label">[2]</span></a> The views of Dr. Hibbert are not inconsistent with those of the
+late Sir A. Ramsay, on "The Physical History of the Valley of the
+Rhine," <i>Quart. Jour. Geol. Soc.</i>, vol. xxx. (1874).</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_94" id="Footnote_3_94"></a><a href="#FNanchor_3_94"><span class="label">[3]</span></a> Von Dechen, <i>Geog. Beschreib. des Siebengebirges am Rhein</i>
+(Bonn, 1852).</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_95" id="Footnote_4_95"></a><a href="#FNanchor_4_95"><span class="label">[4]</span></a> Hibbert, <i>loc. cit.</i>, p. 18.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_96" id="Footnote_5_96"></a><a href="#FNanchor_5_96"><span class="label">[5]</span></a> Horner, "Geology of Environs of Bonn," <i>Transactions of the
+Geological Society</i>, vol. iv., new series.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_97" id="Footnote_6_97"></a><a href="#FNanchor_6_97"><span class="label">[6]</span></a> H. von Dechen, <i>Geog. Führer in das Siebengebirge am Rhein</i>
+(Bonn, 1861).</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_98" id="Footnote_7_98"></a><a href="#FNanchor_7_98"><span class="label">[7]</span></a> <i>Ibid.</i>, p. 191.</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_99" id="Footnote_8_99"></a><a href="#FNanchor_8_99"><span class="label">[8]</span></a> Dr. Hibbert's work is illustrated by very carefully drawn and
+accurate views of some of the old cones and craters of this district,
+accompanied by detailed descriptions.</p></div>
+
+<div class="footnote"><p><a name="Footnote_9_100" id="Footnote_9_100"></a><a href="#FNanchor_9_100"><span class="label">[9]</span></a> The lava of Schorenberg, near Rieden, is interesting from the fact,
+stated by Zirkel, that it contains leucite, nosean, and nephelin.&mdash;<i>Die
+Mikros. Beschaf. d. Miner. u. Gesteine</i>, p. 154 (1873).</p></div>
+
+<div class="footnote"><p><a name="Footnote_10_101" id="Footnote_10_101"></a><a href="#FNanchor_10_101"><span class="label">[10]</span></a> Hibbert, <i>loc. cit.</i>, p. 23.</p></div>
+
+<div class="footnote"><p><a name="Footnote_11_102" id="Footnote_11_102"></a><a href="#FNanchor_11_102"><span class="label">[11]</span></a> At the time of the author's visit the underground caverns, which are
+deliciously cool in summer, were used for the storage of the celebrated
+beer brewed by the Moravians of Neuwied.</p></div>
+
+<div class="footnote"><p><a name="Footnote_12_103" id="Footnote_12_103"></a><a href="#FNanchor_12_103"><span class="label">[12]</span></a> Hibbert, <i>loc. cit.</i>, p. 129.</p></div>
+<p><span class="pagenum"><a name="Page_126" id="Page_126">[Pg 126]</a></span></p>
+
+
+<hr class="major" />
+<h1><a name="PART_III" id="PART_III"></a>PART III.
+<br /><br />
+DORMANT OR MORIBUND VOLCANOES OF
+OTHER PARTS OF THE WORLD.</h1>
+
+
+
+<hr class="major" />
+<h2><a name="PART_III_CHAPTER_I" id="PART_III_CHAPTER_I"></a>CHAPTER I.
+<br /><br />
+DORMANT VOLCANOES OF PALESTINE AND ARABIA.</h2>
+
+
+<p>(<i>a.</i>) <i>Region east of the Jordan and Dead Sea.</i>&mdash;The
+remarkable line of country lying along the valley of
+the Jordan, and extending into the great Arabian
+Desert, has been the seat of extensive volcanic action
+in prehistoric times. The specially volcanic region
+seems to be bounded by the depression of the Jordan,
+the Dead Sea, and the Arabah as far south as the Gulf
+of Akabah; for, although Safed, lying at the head of
+the Sea of Galilee on the west of the Jordan valley, is
+built on a basaltic sheet, and is in proximity to an
+extinct crater, its position is exceptional to the general
+arrangement of the volcanic products which may be
+traced at intervals from the base of Hermon into
+Central Arabia, a distance of about 1000 miles.<a name="FNanchor_1_104" id="FNanchor_1_104"></a><a href="#Footnote_1_104" class="fnanchor">[1]</a></p>
+
+<p>The tract referred to has been described at intervals
+<span class="pagenum"><a name="Page_127" id="Page_127">[Pg 127]</a></span>by several authors, of whom G. Schumacher,<a name="FNanchor_2_105" id="FNanchor_2_105"></a><a href="#Footnote_2_105" class="fnanchor">[2]</a> L. Lartet,<a name="FNanchor_3_106" id="FNanchor_3_106"></a><a href="#Footnote_3_106" class="fnanchor">[3]</a>
+Canon Tristram,<a name="FNanchor_4_107" id="FNanchor_4_107"></a><a href="#Footnote_4_107" class="fnanchor">[4]</a> M. Niebuhr,<a name="FNanchor_5_108" id="FNanchor_5_108"></a><a href="#Footnote_5_108" class="fnanchor">[5]</a> and C. M. Doughty<a name="FNanchor_6_109" id="FNanchor_6_109"></a><a href="#Footnote_6_109" class="fnanchor">[6]</a>
+may be specially mentioned in this connection.</p>
+
+<p>The most extensive manifestations of volcanic energy
+throughout this long tract of country appear to be
+concentrated at its extreme limits. At the northern
+extremity the generally wild and rugged tract of the
+Jaulân and Haurân, called in the Bible <i>Trachonitis</i>,
+and still farther to the eastward the plateau of the
+Lejah, with its row of volcanic peaks sloping down to
+the vast level of Bashan, is covered throughout nearly
+its whole extent by great sheets of basaltic lava,
+above which rise at intervals, and in very perfect form,
+the old crater-cones of eruption. A similar group of
+extinct craters with lava-flows has been described and
+figured by a recent traveller, Mr. C. M. Doughty, in
+parts of Central Arabia. The general resemblance of
+these Arabian volcanoes to those of the Jaulân is
+unquestionable; and as they are connected with each
+other by sheets of basaltic lava at intervals throughout
+the land of Moab, it is tolerably certain that the
+volcanoes lying at either end of the chain belong to
+one system, and were contemporaneously in a state of
+activity.</p>
+
+<p>(<i>b.</i>) <i>Geological Conditions.</i>&mdash;Before entering any
+<span class="pagenum"><a name="Page_128" id="Page_128">[Pg 128]</a></span>further into particulars regarding the volcanic phenomena
+of this region, it may be desirable to give a
+short account of its geological structure, and the
+physical conditions amongst which the igneous eruptions
+were developed.</p>
+
+<p>Down to the close of the Eocene period the whole
+region now under consideration was occupied by the
+waters of the ocean. The mountains of Sinai were
+islands in this ocean, which had a very wide range
+over parts of Asia, Africa, and Europe. But at the
+commencement of the succeeding Miocene stage the
+crust was subjected to lateral contraction, owing to
+which the ocean bed was upraised. The strata were
+flexured, folded, and often faulted and fissured along
+lines ranging north and south, the great fault of the
+Jordan-Arabah valley being the most important. At
+this period the mountains of the Lebanon, the table-lands
+of Judæa and of Arabia, formed of limestone,
+previously constituting the bed of the ocean during the
+Eocene and Cretaceous periods, were converted into
+land surfaces. Along with this upheaval of the sea-bed
+there was extensive denudation and erosion of the
+strata, so that valleys were eroded over the subaërial
+tracts, and the Jordan-Arabah valley received its
+primary form and outline.</p>
+
+<p>Up to this time there does not appear to have been
+any outbreak of volcanic forces; but with the succeeding
+Pliocene period these came into play, and eruptions
+of basaltic lava took place along rents and
+fissures in the strata, while craters and cones of slag,
+scoriæ, and ashes were thrown up over the region
+lying to the east of the Sea of Galilee and the sources
+of the Jordan on the one hand, and the central parts
+of the great Arabian Desert on the other. These
+<span class="pagenum"><a name="Page_129" id="Page_129">[Pg 129]</a></span>eruptions, probably intermittent, continued into the
+succeeding Glacial or Pluvial period, and only died
+out about the time that the earliest inhabitants
+appeared on the scene.</p>
+
+<p>(<i>c.</i>) <i>The Jaulân and Haurân.</i>&mdash;This tract is bounded
+by the valley of the Jordan and the Sea of Galilee on
+the west, from which it rises by steep and rocky
+declivities into an elevated table-land, drained by the
+Yarmûk (Hieromax), the Nahr er Rukkâd, and other
+streams, which flow westwards into the Jordan along
+deep channels in which the basaltic sheets and underlying
+limestone strata are well laid open to view.</p>
+
+<p>On consideration it seems improbable that the great
+sheets of augitic lava, such as cover the surface of
+the land of Bashan, are altogether the product of the
+volcanic mountains which appear to be confined to
+special districts in this wide area. Some of the craters
+do indeed send forth visible lava-streams, but they are
+insignificant as compared with the general mass of
+the plateau-basalts; and the crater-cones themselves
+appear in some cases to be posterior to the platforms
+of basalt from which they rise. It is very probable,
+therefore, that the lavas of this region have, in the
+main, been extruded from fissures of eruption at an
+early period, and spread over the surface of the
+country in the same manner as those of the Snake
+River region, and the borders of the Pacific Ocean of
+North America, and possibly of the Antrim Plateau
+in Ireland, afterwards to be described.</p>
+
+<p>The volcanic hills which rise above the plateau are
+described in detail by Schumacher. Of these, Tell
+Abû Nedîr is the largest in the Jaulân. It reaches an
+elevation of 4132 feet above the Mediterranean Sea,
+and 1710 feet above the plain from which it rises;
+<span class="pagenum"><a name="Page_130" id="Page_130">[Pg 130]</a></span>the circumference of its base is three miles, and the
+rim of the crater itself, which is oval in form, is
+1331 yards in its larger diameter. The interior is
+cultivated by Circassians, and is very fruitful; the
+walls descend at an angle of about 30° on the inside,
+the exterior slope of the mountain being about 22°.
+The cone seems to be formed chiefly of scoriæ, and
+the lava-stream, which issues forth from the interior,
+forms a frightfully stony and lacerated district.<a name="FNanchor_7_110" id="FNanchor_7_110"></a><a href="#Footnote_7_110" class="fnanchor">[7]</a></p>
+
+<div class="figcenter">
+<a name="FIGURE_24">
+  <img src="images/figure24.jpg" alt="Craters in the Jaulân" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 24.</span>&mdash;Extinct Craters in the Jaulân, north-east from the Sea of
+Galilee, called Tell Abû en Nedâ and Tell el Urâm, with a central
+cone.&mdash;(After Schumacher.)
+</td></tr>
+</table>
+</div>
+
+<p>Another remarkable volcano is the Tell Abû en
+Nedâ (<a href="#FIGURE_24">Fig. 24</a>). This is a double crater, with a
+cone (probably of cinders) rising from the interior
+of one of them. The highest point of the rim of
+one of the craters reaches a level of 4042 feet above
+the sea. A lava-stream issues forth from Abû en
+Nedâ, and unites with another from a neighbouring
+volcano.</p>
+
+<p><span class="pagenum"><a name="Page_131" id="Page_131">[Pg 131]</a></span></p><p>Tell el Ahmâr is a ruptured crater of imposing
+aspect, reaching an elevation of 4060 feet, and sending
+forth a lava-current, which falls in regular terraces
+from the outlet towards the west and north.</p>
+
+<p>The ruptured crater of Tell el Akkasheh, which
+reaches a height of 3400 feet, has a less forbidding
+aspect than the greater number of the extinct
+volcanoes of this region, owing to the fact that its
+sides are covered by oaks, which attain to magnificent
+proportions along the summit. Numerous other
+volcanic hills occur in this district, but the most
+remarkable is that called Tell el Farras (the Hill of
+the Horse). It is an isolated mountain, visible from
+afar, and reaches an elevation of 3110 feet, or nearly
+800 feet above the surrounding plain. The oval
+crater of this volcano opens towards the north, and
+has a depth of 108 feet below the edge, with moderately
+steep sloping sides (17°-32°), while the slope
+of the exterior, at first steep, gradually lessens to
+20°-21°. These slopes are covered with reddish or
+yellowish slag. The above examples will probably
+suffice to afford the reader a general idea of the size
+and form of the volcanoes in this little known
+region.</p>
+
+<p>It has been stated above that the great lava-floods
+have probably been poured forth intermittently.
+The statement receives confirmation from the observations
+of Canon Tristram, made in the valley of the
+Yarmûk.<a name="FNanchor_8_111" id="FNanchor_8_111"></a><a href="#Footnote_8_111" class="fnanchor">[8]</a> This impetuous torrent rushes down a
+gorge, sometimes having limestone on one side and a
+wall of basalt on the other. This is due to the fact
+that the river channel had been eroded before the
+volcanic eruptions had commenced; but on the lava-stream
+<span class="pagenum"><a name="Page_132" id="Page_132">[Pg 132]</a></span>reaching the channel, it naturally descended
+towards the valley of the Jordan along its bed, displacing
+the river, or converting it into clouds of
+steam. Subsequently the river again hewed out its
+channel, sometimes in the lava, sometimes between
+this rock and the chalky limestone. But, in addition
+to this, it has been observed that there is a bed of
+river gravel interposed between two sheets of basalt
+in the Yarmûk ravine; showing that after the first
+flow of that molten rock the river reoccupied its
+channel, which was afterwards invaded by another
+molten lava-stream, into which the waters have again
+furrowed the channel which they now occupy. The
+basaltic sheets descend under the waters of the Sea of
+Galilee on the east side, and were probably connected
+with those of Safed, crossing the Jordan valley north
+of that lake; owing to this the waters of the Lake of
+Merom (Huleh) were pent up, and formerly covered
+an extensive tract, now formed of alluvial deposits.</p>
+
+<p>(<i>d.</i>) <i>Land of Moab.</i>&mdash;Proceeding southwards into
+the Land of Moab, the volcanic phenomena are here
+of great interest. Extensive sheets of basaltic lava,
+described as far back as 1807 by Seetzen, and more
+recently by Lartet and Tristram, are found at intervals
+between the Wâdies Mojib (Arnon) and Haidan. On
+either side of the Mojib, cliffs of columnar basalt are
+seen capping the beds of white Cretaceous limestone,
+while a large mass has descended into the W.
+Haidan between cliffs of limestone and marl on either
+hand.</p>
+
+<p>Around Jebel Attarus&mdash;a dome-shaped hill of limestone&mdash;a
+sheet of basaltic lava has been poured, and
+has descended the deep gorge of the Zerka Maïn,
+which enters the Dead Sea some 2000 feet below.
+<span class="pagenum"><a name="Page_133" id="Page_133">[Pg 133]</a></span>This gorge had been eroded before the basaltic
+eruption, so that the stream of molten lava took its
+course down the bed of this stream to the water's
+edge, and grand sections have been laid bare by
+subsequent erosion along the banks. Pentagonal
+columns of black basalt form perpendicular walls,
+first on one side, then on the other; while considerable
+masses of scoriæ, peperino, and breccia appear at the
+head of the glen, probably marking the orifice of
+eruption. Other eruptions of basalt occur, one at
+Mountar ez Zara, to the south of Zerka Maïn, and
+another at Wady Ghuweir, near the north-eastern
+end of the Dead Sea. There are no lava-streams on
+the western side of the Ghor, or of the Dead Sea.<a name="FNanchor_9_112" id="FNanchor_9_112"></a><a href="#Footnote_9_112" class="fnanchor">[9]</a></p>
+
+<p>The outburst of the celebrated thermal springs of
+Callirrhoë, together with nine or ten others, along the
+channel of the Zerka Maïn, is a circumstance which
+cannot be dissociated from the occurrence of basaltic
+lava at this spot. In a reach of three miles, according
+to Tristram, there are ten principal springs, of which
+the fifth in descent is the largest; but the seventh
+and eighth, about half a mile lower down, are the
+most remarkable, giving forth large supplies of sulphurous
+water. The tenth and last is the hottest of
+all, indicating a temperature of 143° Fahr. Thus it
+would appear that the heat increases with the depth
+from the upper surface of the table-land; a result
+which might be expected, supposing the heated
+volcanic rocks to be themselves the source of the high
+temperature. To a similar cause may be attributed
+the hot-springs of Hammath, near Tiberias, and those
+of the Yarmûk near its confluence with the Jordan.
+<span class="pagenum"><a name="Page_134" id="Page_134">[Pg 134]</a></span>Some of these and other springs break out along, or
+near, the line of the great Jordan-Arabah fault which
+ranges throughout the whole extent of this depression,
+from the base of Hermon to the Gulf of Akabah,
+generally keeping close to the eastern margin of the
+valley.</p>
+
+<p>(<i>e.</i>) <i>The Arabian Desert.</i>&mdash;The basaltic lava-floods
+occupy a very large extent of the Arabian Desert,
+from El Hisma (lat. 27° 35' N.) to the neighbourhood
+of Mecca on the south, a distance of about 440 miles,
+with occasional intervals. The lava-sheets are called
+"Harras" (or "Harrat"), one of which, Harrat Sfeina,
+terminates about ten miles north of Mecca. The
+lava-sheets rest sometimes on the red sandstone, at
+other times, on the granite and other crystalline rocks
+of great geological antiquity. In addition to the
+sheets of basalt, numerous crater-cones rise from the
+basaltic platform at a level of 5000 feet above the sea,
+and two volcanic mountains, rising far to the west
+of the principal range, called respectively Harrât
+Jeheyma and H. Rodwa, almost overlook the coast
+of the Red Sea.<a name="FNanchor_10_113" id="FNanchor_10_113"></a><a href="#Footnote_10_113" class="fnanchor">[10]</a></p>
+
+<p>(<i>f.</i>) <i>Age of the Volcanic Eruptions.</i>&mdash;It is very clear
+that the first eruptions, producing the great basaltic
+sheets of Moab and Arabia, occurred after the principal
+features of the country had been developed. The
+depression of the Jordan-Arabah valley, the elevation
+of the eastern side of this valley along the great
+fault line, and the channels of the principal tributary
+streams, such as those of the Yarmûk and Zerka
+Maïn, all these had been eroded out before they were
+invaded by the molten streams of lava. Now, as these
+<span class="pagenum"><a name="Page_135" id="Page_135">[Pg 135]</a></span>physical features were developed and sculptured out
+during the Miocene period, as I have elsewhere shown
+to be the case,<a name="FNanchor_11_114" id="FNanchor_11_114"></a><a href="#Footnote_11_114" class="fnanchor">[11]</a> we may with great probability refer the
+volcanic eruptions to the geological epoch following&mdash;namely,
+the Pliocene. How far downwards towards
+the historic period the eruptions continued is not so
+certain. Dr. Daubeny, quoting several passages from
+the Old Testament prophets,<a name="FNanchor_12_115" id="FNanchor_12_115"></a><a href="#Footnote_12_115" class="fnanchor">[12]</a> says it might be inferred
+that volcanoes were in activity even so late as to
+admit of their being included within the limits of
+authentic history. The poetic language and imagery
+used in these passages by the prophets certainly lends
+a probability to this view, but nothing more. On the
+other hand, these regions have suffered through many
+centuries from the secondary effects of seismic action
+and subterranean forces, and earthquake shocks have
+laid in ruins the great temples and palaces of Palmyra,
+Baalbec, and other cities of antiquity. The
+same uncertainty regarding the time at which volcanic
+action died out, with reference to the appearance of
+man on the scene, hangs over the region of Arabia
+and Syria, as we have seen to be the case in reference
+to the extinct volcanoes of Auvergne, the Eifel, and
+the Lower Rhine. In all these cases the commencement
+and close of eruptive action appear to have
+been very much about the same period&mdash;namely, the
+Miocene period on the one hand, and that at which
+man entered upon the scene on the other; but in the
+case of Syria and Western Palestine, the close of the
+volcanic period may have been somewhat more than
+2000 <span class="smcap">B.C.</span></p>
+
+<div class="footnote"><p><a name="Footnote_1_104" id="Footnote_1_104"></a><a href="#FNanchor_1_104"><span class="label">[1]</span></a> Lake Phiala, near the Lake of Huleh, is also situated to the west
+of the Jordan valley. Its origin, according to Tristram, is volcanic.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_105" id="Footnote_2_105"></a><a href="#FNanchor_2_105"><span class="label">[2]</span></a> Schumacher, "The Jaulân," <i>Quarterly Statement of the Palestine
+Exploration Fund</i>, 1886 and 1888; and <i>Across the Jordan</i>, London,
+1886.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_106" id="Footnote_3_106"></a><a href="#FNanchor_3_106"><span class="label">[3]</span></a> Lartet, <i>Voyage d'Exploration de la mer Morte</i> (Géologie), Paris,
+1880.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_107" id="Footnote_4_107"></a><a href="#FNanchor_4_107"><span class="label">[4]</span></a> Tristram, <i>Land of Moab</i>, London, 1873; and <i>Land of Israel</i>, 1866.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_108" id="Footnote_5_108"></a><a href="#FNanchor_5_108"><span class="label">[5]</span></a> Niebuhr, <i>Beschreibung von Arabien</i>, 1773.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_109" id="Footnote_6_109"></a><a href="#FNanchor_6_109"><span class="label">[6]</span></a> C. M. Doughty, <i>Arabia Deserta</i>, 2 vols., 1888. A generalised
+account of this volcanic region by the author will be found in the
+"Memoir on the Physical Geology of Arabia Petræa, and Palestine,"
+<i>Palestine Exploration Fund</i>, 1887.</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_110" id="Footnote_7_110"></a><a href="#FNanchor_7_110"><span class="label">[7]</span></a> Schumacher, <i>loc. cit.</i>, p. 248.</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_111" id="Footnote_8_111"></a><a href="#FNanchor_8_111"><span class="label">[8]</span></a> <i>Land of Israel</i>, p. 461.</p></div>
+
+<div class="footnote"><p><a name="Footnote_9_112" id="Footnote_9_112"></a><a href="#FNanchor_9_112"><span class="label">[9]</span></a> "Geology of Arabia Petræa, and Palestine," <i>Memoirs of the
+Palestine Exploration Fund</i>, p. 95.</p></div>
+
+<div class="footnote"><p><a name="Footnote_10_113" id="Footnote_10_113"></a><a href="#FNanchor_10_113"><span class="label">[10]</span></a> Doughty, <i>loc. cit.</i>, vol. i., plate vi., p. 416. An excellent geological
+sketch map accompanies this work.</p></div>
+
+<div class="footnote"><p><a name="Footnote_11_114" id="Footnote_11_114"></a><a href="#FNanchor_11_114"><span class="label">[11]</span></a> "Memoir of the Geology of Arabia Petræa, and Palestine," chap.
+vi. p. 67.</p></div>
+
+<div class="footnote"><p><a name="Footnote_12_115" id="Footnote_12_115"></a><a href="#FNanchor_12_115"><span class="label">[12]</span></a> Nahum, i. 5, 6; Micah, i. 3, 4; Isaiah, lxiv. 1-3; Jeremiah, l. 25.</p></div>
+<p><span class="pagenum"><a name="Page_136" id="Page_136">[Pg 136]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_III_CHAPTER_II" id="PART_III_CHAPTER_II"></a>CHAPTER II.
+<br /><br />
+THE VOLCANIC REGIONS OF NORTH AMERICA.</h2>
+
+
+<p>(<i>a.</i>) <i>Contrast between the Eastern and Western
+Regions.</i>&mdash;In no point is there a more remarkable
+contrast between the physical structure of Eastern
+and Western America than in the absence of volcanic
+phenomena in the former and their prodigious development
+in the latter. The great valley of the Mississippi
+and its tributaries forms the dividing territory
+between the volcanic and non-volcanic areas; so that
+on crossing the high ridges in which the western
+tributaries of America's greatest river have their
+sources, and to which the name of the "Rocky Mountains"
+more properly belongs, we find ourselves in a
+region which, throughout the later Tertiary times down
+almost to the present day, has been the scene of
+volcanic operations on the grandest scale; where
+lava-floods have been poured over the country through
+thousands of square miles, and where volcanic cones,
+vying in magnitude with those of Etna, Vesuvius, or
+Hecla, have established themselves. This region,
+generally known as "The Great Basin," is bounded
+on the west by the "Pacific Range" of mountains,
+and includes portions of New Mexico, Arizona,
+California, Nevada, Utah, Colorado, Idaho, Oregon,
+Wyoming, Montana, and Washington. To the south
+<span class="pagenum"><a name="Page_137" id="Page_137">[Pg 137]</a></span>it passes into the mountainous region of Mexico, also
+highly volcanic; and thence into the ridge of Panama
+and the Andes. It cannot be questioned but that
+the volcanic nature of the Great Basin is due to the
+same causes which have originated the volcanic outbursts
+of the Andes; but, from whatever cause, the
+volcanic forces have here entered upon their secondary
+or moribund stage. In the Yellowstone Valley,
+geysers, hot springs, and fumaroles give evidence of
+this condition. In other districts the lava-streams
+are so fresh and unweathered as to suggest that they
+had been erupted only a few hundred years ago; but
+no active vent or crater is to be found over the whole
+of this wide region. A few special districts only can
+here be selected by way of illustration of its special
+features in connection with its volcanic history.</p>
+
+<p>(<i>b.</i>) <i>The Plateau Country of Utah and Arizona.</i>&mdash;This
+tract, which is drained by the Colorado River
+and its tributaries, is bounded on the north by the
+Wahsatch range, and extends eastwards to the base
+of the Sierra Nevada. Round its margin extensive
+volcanic tracts are to be found, with numerous peaks
+and truncated cones&mdash;the ancient craters of eruption&mdash;of
+which Mount San Francisco is the culminating
+eminence. South of the Wahsatch, and occupying the
+high plateaux of Utah, enormous masses of volcanic
+products have been spread over an area of 9000 square
+miles, attaining a thickness of between 3000 and 4000
+feet. The earlier of these great lava-floods appear to
+have been trachytic, but the later basaltic; and in the
+opinion of Captain Dutton, who has described them,
+they range in point of time from the Middle Tertiary
+(Miocene) down to comparatively recent times.</p>
+
+<p>(<i>c.</i>) <i>The Grand Cañon.</i>&mdash;To the south of the high
+<span class="pagenum"><a name="Page_138" id="Page_138">[Pg 138]</a></span>plateaux of Utah are many minor volcanic mountains,
+now extinct; and as we descend towards the Grand
+Cañon of Colorado we find numerous cinder-cones
+scattered about at intervals near the cliffs.<a name="FNanchor_1_116" id="FNanchor_1_116"></a><a href="#Footnote_1_116" class="fnanchor">[1]</a> Extensive
+lava-fields, surmounted by cinder-cones, occupy the
+plateau on the western side of the Grand Cañon; and,
+according to Dutton, the great sheets of basaltic lava,
+of very recent age, which occupy many hundred square
+miles of desert, have had their sources in these cones of
+eruption.<a name="FNanchor_2_117" id="FNanchor_2_117"></a><a href="#Footnote_2_117" class="fnanchor">[2]</a> Crossing to the east of the Grand Cañon,
+we find other lava-floods poured over the country at
+intervals, surmounted by San Francisco&mdash;a volcanic
+mountain of the first magnitude&mdash;which reaches an
+elevation, according to Wheeler, of 12,562 feet above
+the ocean. It has long been extinct, and its summit
+and flanks are covered with snow-fields and glaciers.
+Other parts of Arizona are overspread by sheets of
+basaltic lava, through which old "necks" of eruption,
+formed of more solid lava than the sheets, rise occasionally
+above the surface, and are prominent features in
+the landscape.</p>
+
+<p>Further to the eastward in New Mexico, and near
+the margin of the volcanic region, is another volcanic
+mountain little less lofty than San Francisco, called
+Mount Taylor, which, according to Dutton, rises to
+an elevation of 11,390 feet above the ocean, and 8200
+feet above the general level of the surrounding plateau
+of lava. This mountain forms the culminating point
+of a wide volcanic tract, over which are distributed
+<span class="pagenum"><a name="Page_139" id="Page_139">[Pg 139]</a></span>numberless vents of eruption. Scores of such vents&mdash;generally
+cinder-cones&mdash;are visible in every part
+of the plateau, and always in a more or less dilapidated
+condition.<a name="FNanchor_3_118" id="FNanchor_3_118"></a><a href="#Footnote_3_118" class="fnanchor">[3]</a> Mount Taylor is a volcano, with a
+central pipe terminating in a large crater, the wall of
+which was broken down on the east side in the later
+stage of its history.</p>
+
+<div class="figcenter">
+<a name="FIGURE_25">
+  <img src="images/figure25.jpg" alt="Mount Shasta" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 25.</span>&mdash;Mount Shasta (14,511 feet), a snow-clad volcanic cone in California, with Mount Shastina, a secondary crater,
+on the right; the valley between is filled with glacier-ice.&mdash;(After Dutton).
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_140" id="Page_140">[Pg 140]</a></span></p><p>(<i>d.</i>) <i>California.</i>&mdash;Proceeding westwards into California,
+we are again confronted with volcanic phenomena
+on a stupendous scale. The coast range of
+mountains, which branches off from the Sierra
+Nevada at Mount Pinos, on the south, is terminated
+near the northern extremity of the State by a very
+lofty mountain of volcanic origin, called Mount
+Shasta, which attains an elevation of 14,511 feet
+(see <a href="#FIGURE_25">Fig. 25</a>). This mountain was first ascended by
+Clarence King in 1870,<a name="FNanchor_4_119" id="FNanchor_4_119"></a><a href="#Footnote_4_119" class="fnanchor">[4]</a> and although forming, as
+it were, a portion of the Pacific Coast Range, it
+really rises from the plain in solitary grandeur, its
+summit covered by snow, and originating several
+fine glaciers.</p>
+
+<p>The summit of Mount Shasta is a nearly perfect
+cone, but from its north-west side there juts out a
+large crater-cone just below the snow-line, between
+which and the main mass of the mountain there
+exists a deep depression filled with glacier ice. This
+secondary crater-cone has been named Mount
+Shastina, and round its inner side the stream of
+glacier ice winds itself, sometimes surmounting the
+rim of the crater, and shooting down masses of ice
+<span class="pagenum"><a name="Page_141" id="Page_141">[Pg 141]</a></span>into the great caldron. The length of this glacier is
+about three miles, and its breadth about 4000 feet.
+Another very lofty volcanic mountain is Mount
+Rainier, in the Washington territory, consisting of
+three peaks of which the eastern possesses a crater
+very perfect throughout its entire circumference.
+This mountain appears to be formed mainly of
+trachytic matter. Proceeding further north into
+British territory, several volcanic mountains near
+the Pacific Coast are said to exhibit evidence of
+activity. Of these may be mentioned Mount Edgecombe,
+in lat. 57°.3; Mount Fairweather, lat. 57°.20
+which rises to a height of 14,932 feet; and Mount
+St. Elias, lat. 60°.5, just within the divisional line
+between British and Russian territory, and reaching
+an altitude of 16,860 feet. This, the loftiest of all the
+volcanoes of the North American continent, except
+those of Mexico, may be considered as the connecting
+link in the volcanic chain between the continent
+and the Aleutian Islands.<a name="FNanchor_5_120" id="FNanchor_5_120"></a><a href="#Footnote_5_120" class="fnanchor">[5]</a></p>
+
+<p>(<i>e.</i>) <i>Lake Bonneville.</i>&mdash;Returning to Utah we are
+brought into contact with phenomena of special
+interest, owing to the inter-relations of volcanic and
+lacustrine conditions which once prevailed over large
+tracts of that territory. The present Great Salt
+Lake, and the smaller neighbouring lakes, those called
+Utah and Sevier, are but remnants of an originally
+far greater expanse of inland water, the boundaries
+of which have been traced out by Mr. C. K. Gilbert,
+and described under the name of Lake Bonneville.<a name="FNanchor_6_121" id="FNanchor_6_121"></a><a href="#Footnote_6_121" class="fnanchor">[6]</a>
+The waters of this lake appear to have reached their
+highest level at the period of maximum cold of the
+<span class="pagenum"><a name="Page_142" id="Page_142">[Pg 142]</a></span>Post-Pliocene period, when the glaciers descended
+to its margin, and large streams of glacier water
+were poured into it. Eruptions of basaltic lava from
+successive craters appear to have gone on before,
+during, and after the lacustrine epochs; and the drying
+up of the waters over the greater extent of their
+original area, now converted into the Sevier Desert,
+and their concentration into their present comparatively
+narrow basins, appears to have proceeded <i>pari
+passu</i> with the gradual extinction of the volcanic outbursts.
+Two successive epochs of eruption of basalt
+appear to have been clearly established&mdash;an earlier
+one of the "Provo Age," when the lava was extruded
+from the Tabernacle craters, and a later epoch, when
+the eruptions took place from the Ice Spring craters.
+The oldest volcanic rock appears to be rhyolite,
+which peers up in two small hills almost smothered
+beneath the lake deposits. Its eruption was long
+anterior to the lake period. On the other hand, the
+cessation of the eruptions of the later basaltic sheets
+is evidently an event of such recent date that Mr.
+Gilbert is led to look forward to their resumption at
+some future, but not distant, epoch. As he truly
+observes, we are not to infer that, because the outward
+manifestations of volcanic action have ceased,
+the internal causes of those manifestations have
+passed away. These are still in operation, and must
+make themselves felt when the internal forces have
+recovered their exhausted energies; but perhaps not
+to the same extent as before.</p>
+
+<p>(<i>f.</i>) <i>Region of the Snake River.</i>&mdash;The tract of
+country bordering the Snake River in Idaho and
+Washington is remarkable for the vast sheets of
+plateau-basalt with which it is overspread, extending
+<span class="pagenum"><a name="Page_143" id="Page_143">[Pg 143]</a></span>sometimes in one great flood farther than the eye can
+reach, and what is still more remarkable, they are
+often unaccompanied by any visible craters or vents
+of eruption. In Oregon the plateau-basalt is at least
+2,000 feet in thickness, and where traversed by the
+Columbia River it reaches a thickness of about 3,000
+feet. The Snake and Columbia rivers are lined by
+walls of volcanic rock, basaltic above, trachytic below,
+for a distance of, in the former, one hundred, in the
+latter, two hundred, miles. Captain Dutton, in describing
+the High Plateau of Utah, observes that the
+lavas appear to have welled up in mighty floods
+without any of that explosive violence generally
+characteristic of volcanic action. This extravasated
+matter has spread over wide fields, deluging the
+surrounding country like a tide in a bay, and overflowing
+all inequalities. Here also we have evidence
+of older volcanic cones buried beneath seas of lava
+subsequently extruded.</p>
+
+<p>(<i>g.</i>) <i>Fissures of Eruption.</i>&mdash;The absence, or rarity, of
+volcanic craters or cones of eruption in the neighbourhood
+of these great sheets has led American geologists
+to the conclusion that the lavas were in many cases
+extruded from fissures in the earth's crust rather than
+from ordinary craters.<a name="FNanchor_7_122" id="FNanchor_7_122"></a><a href="#Footnote_7_122" class="fnanchor">[7]</a> This view is also urged by
+Sir A. Geikie, who visited the Utah region of the
+Snake River in 1880, and has vividly described the
+impression produced by the sight of these vast fields
+of basaltic lava. He says, "We found that the older
+trachytic lavas of the hills had been deeply trenched
+by the lateral valleys, and that all these valleys had a
+floor of black basalt that had been poured out as the last
+<span class="pagenum"><a name="Page_144" id="Page_144">[Pg 144]</a></span>of the molten materials from the now extinct volcanoes.
+There were no visible cones or vents from which these
+floods of basalt could have proceeded. We rode for
+hours by the margin of a vast plain of basalt stretching
+southward and westward as far as the eye could
+reach.... I realised the truth of an assertion made
+first by Richthofen,<a name="FNanchor_8_123" id="FNanchor_8_123"></a><a href="#Footnote_8_123" class="fnanchor">[8]</a> that our modern volcanoes, such
+as Vesuvius and Etna, present us with by no means
+the grandest type of volcanic action, but rather belong
+to a time of failing activity. There have been periods
+of tremendous volcanic energy, when instead of
+escaping from a local vent, like a Vesuvian cone, the
+lava has found its way to the surface by innumerable
+fissures opened for it in the solid crust of the globe
+over thousands of square miles."<a name="FNanchor_9_124" id="FNanchor_9_124"></a><a href="#Footnote_9_124" class="fnanchor">[9]</a></p>
+
+<p>(<i>h.</i>) <i>Volcanic History of Western America.</i>&mdash;The
+general succession of volcanic events throughout the
+region of Western America appears to have been
+somewhat as follows:&mdash;<a name="FNanchor_10_125" id="FNanchor_10_125"></a><a href="#Footnote_10_125" class="fnanchor">[10]</a></p>
+
+<p>The earliest volcanic eruptions occurred in the later
+Eocene epoch and were continued into the succeeding
+Miocene stage. These consisted of rocks moderately
+rich in silica, and are grouped under the heads of
+propylite and andesite. To these succeeded during
+the Pliocene epoch still more highly silicated rocks of
+trachytic type, consisting of sanidine and oligoclase
+trachytes. Then came eruptions of rhyolite during
+the later Pliocene and Pleistocene epochs; and lastly,
+after a period of cessation, during which the rocks
+just described were greatly eroded, came the great
+<span class="pagenum"><a name="Page_145" id="Page_145">[Pg 145]</a></span>eruptions of basaltic lava, deluging the plains, winding
+round the cones or plateaux of the older lavas,
+descending into the river valleys and flooding the lake
+beds, issuing forth from both vents and fissures, and
+continuing intermittently down almost into the present
+day&mdash;certainly into the period of man's appearance
+on the scene. Thus the volcanic history of Western
+America corresponds remarkably to that of the European
+regions with which we have previously dealt,
+both as regards the succession of the various lavas
+and the epochs of their eruption.</p>
+
+<p>(<i>i.</i>) <i>The Yellowstone Park.</i>&mdash;The geysers and hot
+springs of the Yellowstone Park, like those in Iceland
+and New Zealand, are special manifestations of volcanic
+action, generally in its secondary or moribund stage.
+The geysers of the Yellowstone occur on a grand
+scale; the eruptions are frequent, and the water is
+projected into the air to a height of over 200 feet.
+Most of these are intermittent, like the remarkable
+one known as Old Faithful, the Castle Geyser, and
+the Giantess Geyser described by Dr. Hayden, which
+ejects the water to a height of 250 feet. The
+geyser-waters hold large quantities of silica and
+sulphur in solution, owing to their high temperature
+under great pressure, and these minerals are precipitated
+upon the cooling of the waters in the air, and
+form circular basins, often gorgeously tinted with red
+and yellow colours.<a name="FNanchor_11_126" id="FNanchor_11_126"></a><a href="#Footnote_11_126" class="fnanchor">[11]</a></p>
+
+<div class="footnote"><p><a name="Footnote_1_116" id="Footnote_1_116"></a><a href="#FNanchor_1_116"><span class="label">[1]</span></a> J. W. Powell, <i>Exploration of the Cañons of the Colorado</i>, pp. 114,
+196. Major Powell describes a fault or fissure through which floods of
+lava have been forced up from beneath and have been poured over the
+surface. Many cinder-cones are planted along the line of this fissure.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_117" id="Footnote_2_117"></a><a href="#FNanchor_2_117"><span class="label">[2]</span></a> Capt. C. E. Dutton. <i>Sixth Ann. Rep. U.S. Geol. Survey</i>,
+1884-85.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_118" id="Footnote_3_118"></a><a href="#FNanchor_3_118"><span class="label">[3]</span></a> Dutton, <i>loc. cit.</i>, chap. iv. p. 165.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_119" id="Footnote_4_119"></a><a href="#FNanchor_4_119"><span class="label">[4]</span></a> <i>Amer. Jour. Science</i>, vol. 3., ser. (1871). A beautiful map of this
+mountain is given in the <i>Fifth Annual Report, U.S. Geol. Survey</i>,
+1883-84. Plate 44.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_120" id="Footnote_5_120"></a><a href="#FNanchor_5_120"><span class="label">[5]</span></a> Daubeny, <i>loc. cit.</i>, p. 474.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_121" id="Footnote_6_121"></a><a href="#FNanchor_6_121"><span class="label">[6]</span></a> Gilbert, <i>Monograph U.S. Geol. Survey</i>, vol. i. (1890).</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_122" id="Footnote_7_122"></a><a href="#FNanchor_7_122"><span class="label">[7]</span></a> Powell, <i>Exploration of the Colorado River</i>, p. 177, etc. (1875).
+Hayden, <i>Rep. U.S. Geol. Survey of the Colorado, etc.</i> (1871-80).</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_123" id="Footnote_8_123"></a><a href="#FNanchor_8_123"><span class="label">[8]</span></a> Richthofen, <i>Natural System of Volcanic Rocks</i>, Mem. California
+Acad. Sciences, vol. i. (1868).</p></div>
+
+<div class="footnote"><p><a name="Footnote_9_124" id="Footnote_9_124"></a><a href="#FNanchor_9_124"><span class="label">[9]</span></a> Geikie, <i>Geological Sketches at Home and Abroad</i>, p. 271 (1882).</p></div>
+
+<div class="footnote"><p><a name="Footnote_10_125" id="Footnote_10_125"></a><a href="#FNanchor_10_125"><span class="label">[10]</span></a> Prestwich, <i>Geology</i>, vol. i. p. 370, quoting from Richthofen.</p></div>
+
+<div class="footnote"><p><a name="Footnote_11_126" id="Footnote_11_126"></a><a href="#FNanchor_11_126"><span class="label">[11]</span></a> The origin of geysers is variously explained; see Prestwich, <i>Geology</i>,
+vol. i. p. 170. They are probably due to heated waters suddenly converted
+into steam by contact with rock at a high temperature.</p></div>
+<p><span class="pagenum"><a name="Page_146" id="Page_146">[Pg 146]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_III_CHAPTER_III" id="PART_III_CHAPTER_III"></a>CHAPTER III.
+<br /><br />
+VOLCANOES OF NEW ZEALAND.</h2>
+
+
+<p>One other region of volcanic action remains to be
+noticed before passing on to the consideration of
+those of less recent age. New Zealand is an island
+wherein seem to be concentrated all the phenomena
+of volcanic action of past and present time. Though
+it is doubtful if the term "active," in its full sense,
+can be applied to any of the existing craters (with two
+or three exceptions, such as Tongariro and Whakari
+Island), we find craters and cones in great numbers
+in perfectly fresh condition, extensive sheets of
+trachytic and basaltic lavas, ashes, and agglomerates;
+lava-floods descending from the ruptured
+craters of ashes and scoriæ; old crater-basins converted
+into lakes; geysers, hot springs and fumaroles
+which may be counted by hundreds, and cataracts
+breaking over barriers of siliceous sinter; and, lastly,
+lofty volcanic mountains vying in magnitude with
+Vesuvius and Etna. All these wonderful exhibitions
+of moribund volcanic action seem to be concentrated
+in the northern island of Auckland. The
+southern island, which is the larger, also has its
+natural attractions, but they are of a different kind;
+chief of all is the grand range of mountains called, not
+inappropriately, the "Southern Alps," vying with its
+European representative in the loftiness of its peaks
+<span class="pagenum"><a name="Page_147" id="Page_147">[Pg 147]</a></span>and the splendour of its snowfields and glaciers, but
+formed of more ancient and solid rocks than those
+of the northern island.</p>
+
+<p>(<i>a.</i>) <i>Auckland District.</i>&mdash;We are indebted to several
+naturalists for our knowledge of the volcanic regions
+of New Zealand, but chiefly to Ferdinand von Hochstetter,
+whose beautiful maps and graphic descriptions
+leave nothing to be desired.<a name="FNanchor_1_127" id="FNanchor_1_127"></a><a href="#Footnote_1_127" class="fnanchor">[1]</a> In this work Hochstetter
+was assisted by Julius Haast and Sir J. Hector.
+From their account we learn that the Isthmus of
+Auckland is one of the most remarkable volcanic
+districts in the world. It is characterised by a large
+number of extinct cinder-cones, in a greater or less
+perfect state of preservation, and giving origin to
+lava-streams which have poured down the sides of
+the hills on to the plains. Besides these are others
+formed of stratified tuff, with interior craters, surrounding
+in mural cliffs eruptive cones of scoriæ,
+ashes, and lapilli; these cones are scattered over the
+isthmus and shores of Waitemata and Manukau.
+The tuff cones and craters rise from a floor of Tertiary
+sandstone and shale, the horizontal strata of which
+are laid open in the precipitous bluffs of Waitemata
+and Manukau harbours; they sometimes contain
+fossil shells of the genera <i>Pecten</i>, <i>Nucula</i>, <i>Cardium</i>,
+<i>Turbo</i>, and <i>Neritæ</i>. As the volcanic tuff-beds are
+intermingled with the Upper Tertiary strata, it is
+inferred that the first outbursts of volcanic forces
+occurred when the region was still beneath the waters
+of the ocean. Cross-sections show that the different
+layers slope both outwards (parallel to the sides) and
+<span class="pagenum"><a name="Page_148" id="Page_148">[Pg 148]</a></span>inwards towards the bottom of the craters. Sometimes
+these craters have been converted into lakes, as
+in the case of those of the Eifel; but generally they are
+dry or have a floor of morass. Of the crater-lakes,
+those of Kohuora, five in number, are perhaps the
+most remarkable; and in the case of two of these
+the central cones of slag appear as islets rising from
+the surface of the waters. The fresh-water lake
+Pupuka has a depth of twenty-eight fathoms. To
+the north of Auckland Harbour rises out of the waters
+of the Hauraki Gulf the cone of Rangitoto, 920 feet
+high, the flanks formed of rugged streams of basalt,
+and the summit crowned by a circular crater of slag
+and ash, out of the centre of which rises a second
+cone with the vent of eruption. This is the largest
+and newest of the Auckland volcanoes, and appears
+to have been built up by successive outpourings of
+basaltic lava from the central orifice, after the general
+elevation of the island.</p>
+
+<div class="figcenter">
+<a name="FIGURE_26">
+  <img src="images/figure26.jpg" alt="Forms of volcanic tuff cones" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 26.</span>&mdash;Forms of volcanic tuff cones, with their cross-sections, in
+the Province of Auckland.&mdash;No. 1. Simple tuff cone with central crater;
+No. 2. Outer tuff cone with interior cinder cone and crater; No. 3.
+The same with lava-stream issuing from the interior cone.&mdash;(After Hochstetter.)
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_149" id="Page_149">[Pg 149]</a></span></p><p>Before leaving the description of the tuff-cones,
+which are a peculiar feature in the volcanic phenomena
+of New Zealand, and are of many forms
+and varieties, we must refer to that of Mount
+Wellington (Maunga Rei). This is a compound
+volcano, in which the oldest and smallest of the
+group is a tuff-crater-cone, exhibiting very beautifully
+the outward slope of its beds. Within this
+crater arise two cones of cinders, each with small
+craters. It would appear that after a long interval
+the larger of the two principal cones, formed of
+cinders and known as Mount Wellington, burst
+forth from the southern margin of the older tuff-cone,
+and, being built up to a height of 850 feet,
+gradually overspread the sides of its older neighbour.
+Mount Wellington itself has three craters, and from
+these large streams of basaltic lava have issued forth
+in a westerly direction, while a branch entered and
+partially filled the old tuff-crater to the northwards.</p>
+
+<p><span class="pagenum"><a name="Page_150" id="Page_150">[Pg 150]</a></span></p><p>Southwards from Manukau Harbour, and extending
+a short distance from the coast-line to
+Taranaki Point, there occurs a plateau of basalt-conglomerate
+(<i>Basaltkonglomerat</i>), with sheets of
+basaltic lava overspreading the Tertiary strata.
+These plateau-basalts are intersected by eruptive
+masses in the form of dykes, but still there are no
+craters or cones of eruption to be seen; so that we
+may infer that the sheets, at least, were extruded
+from fissures in the manner of those of the Colorado
+or Idaho regions of America. Proceeding still
+further south into the interior of the island, we
+here find a lofty plateau of an average elevation
+of 2,000 feet, interposed between the Tertiary beds
+of the Upper and Middle Waikato, and formed of
+trachytic and pitch-stone tuff, amongst which arise
+old extinct volcanic cones, such as those of Karioi,
+Pirongia, Kakepuku, Maunga Tautari, Aroha, and
+many others. These trachytic lavas would seem
+to be more ancient than the basaltic, previously
+described.</p>
+
+<p>(<i>b.</i>) <i>Taupo Lake, and surrounding district.</i>&mdash;But of
+all these volcanic districts, none is more remarkable
+than that surrounding the Taupo Lake, which lies
+amidst the Tertiary strata of the Upper Waikato
+Basin. The surface of this lake is 1,250 feet above
+that of the ocean, and its margin is enclosed within
+a border of rhyolite and pitchstone&mdash;rising into
+a mass of the same material 1,800 feet high on the
+eastern side. The form of the lake does not suggest
+that it is itself the crater of a volcano, but rather that
+it was originated by subsidence. On all sides, however,
+trachytic cones arise, of which the most remarkable
+group lies to the south of the lake, just
+<span class="pagenum"><a name="Page_151" id="Page_151">[Pg 151]</a></span>in front of the two giant trachytic cones, the loftiest
+in New Zealand, one called Tongariro, rising about
+6,500 feet, and the other Ruapahu, which attains an
+elevation of over 9,000 feet, with the summit capped
+by snow. These two lofty cones, standing side by
+side, are supposed by the Maoris to be the husband
+and wife to whom were born the group of smaller
+cones above referred to as occupying the southern
+shore of Taupo Lake. The volcano of Tongariro
+may still be considered as in a state of activity, as
+its two craters (Ngauruhoe and Ketetahi) constantly
+emit steam, and several solfataras break out on its
+flanks.<a name="FNanchor_2_128" id="FNanchor_2_128"></a><a href="#Footnote_2_128" class="fnanchor">[2]</a></p>
+
+<p>(<i>c.</i>) <i>Roto Mahana.</i>&mdash;In a northerly direction from
+Tongariro, and distant from the coast by a few
+miles, lies in the Bay of Plenty the second of the
+active volcanoes of New Zealand, the volcanic island
+of Whakari (White Island), from the crater of which
+are constantly erupted vast masses of steam clouds.
+The distance between these two active craters
+is 120 nautical miles; and along the tract joining
+them steam-jets and geysers issue forth from the
+deep fissures through which the lava sheets have
+formerly been extruded. Numerous lakes also
+occupy the larger cavities in the ground; and hot-springs,
+steam-fumaroles and solfataras burst out
+in great numbers along the banks of the Roto
+Mahana Lake and the Kaiwaka River by which
+it is drained. Amongst such eruptions of hot-water
+and steam we might expect the formation of siliceous
+sinter, and the deposition of sulphur and other
+minerals; nor will our expectations be disappointed.
+<span class="pagenum"><a name="Page_152" id="Page_152">[Pg 152]</a></span>For here we have the wonderful terraces of siliceous
+sinter deposited by the waters entering Roto Mahana
+as they descend from the numerous hot-springs or
+pools near its margin. All travellers concur in
+describing these terraces as the most wonderful
+of all the wonders of the Lake district of New
+Zealand&mdash;so great is their extent, and so rich and
+varied is their colouring.</p>
+
+<p>The beautiful map of Roto Mahana on an enlarged
+scale by Hochstetter shows no fewer than ten large
+sinter terraces descending towards the margin of this
+lake, besides several mud-springs, fumaroles, and
+solfataras. But the largest and most celebrated of
+all the sinter terraces has within the last few years
+been buried from view beneath a flood of volcanic
+trass, or mud, an event which was as unexpected
+as it was unwelcome. In May, 1887, the mountain
+of Tarawera, which rises to the north-east of Roto
+Mahana, and on the line of eruption above described,
+suddenly burst forth into violent activity, covering
+the country for miles around with clouds of ashes,
+and, pouring down torrents of mud, completely
+enveloped the beautiful terrace of sinter which had
+previously been one of the wonders of New Zealand.
+By the same eruption several human beings were
+entombed, and their residences destroyed.</p>
+
+<p>The waters of Roto Mahana, together with the
+hot-springs and fountains are fed from rain, and
+from the waters of Taupo Lake, which, sinking
+through fissures in the ground, come in contact with
+the interior heated matter, and thus steam at high
+temperature and pressure is generated.<a name="FNanchor_3_129" id="FNanchor_3_129"></a><a href="#Footnote_3_129" class="fnanchor">[3]</a></p>
+
+<p><span class="pagenum"><a name="Page_153" id="Page_153">[Pg 153]</a></span></p><p>(<i>d.</i>) <i>Moribund condition of New Zealand Volcanoes.</i>&mdash;From
+what has been said, it will be inferred that in
+the case of New Zealand, as in those of Auvergne,
+the Eifel and Lower Rhine, Arabia, and Western
+America, we have an example of a region wherein
+the volcanic forces are well-nigh spent, but in which
+they were in a state of extraordinary activity
+throughout the later Tertiary, down to the commencement
+of the present epoch. In most of these
+cases the secondary phenomena of vulcanicity are
+abundantly manifest; but the great exhibitions of
+igneous action, when the plains were devastated by
+sheets of lava, and cones and craters were piled up
+through hundreds and thousands of feet, have for the
+present, at least, passed away.</p>
+
+<div class="footnote"><p><a name="Footnote_1_127" id="Footnote_1_127"></a><a href="#FNanchor_1_127"><span class="label">[1]</span></a> <i>Geol.-topographischer Atlas von Neu-Seeland</i>, von Dr. Ferd. von
+Hochstetter und Dr. A. Petermann. Gotha: Justus Perthes (1863).
+Also <i>New Zealand</i>, trans. by E. Sauter, Stuttgart (1867).</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_128" id="Footnote_2_128"></a><a href="#FNanchor_2_128"><span class="label">[2]</span></a> Tongariro was visited in 1851 by Mr. H. Dyson, who describes the
+eruption of steam.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_129" id="Footnote_3_129"></a><a href="#FNanchor_3_129"><span class="label">[3]</span></a> Mr. Froude figures and describes the two terraces, the "White"
+and "Pink," in <i>Oceana</i>, 2nd edition, pp. 285-291.</p></div>
+<p><span class="pagenum"><a name="Page_154" id="Page_154">[Pg 154]</a></span></p>
+
+
+<hr class="major" />
+<h1><a name="PART_IV" id="PART_IV"></a>PART IV.
+<br /><br />
+TERTIARY VOLCANIC DISTRICTS OF THE
+BRITISH ISLES.</h1>
+
+
+
+<hr class="major" />
+<h2><a name="PART_IV_CHAPTER_I" id="PART_IV_CHAPTER_I"></a>CHAPTER I.
+<br /><br />
+ANTRIM.</h2>
+
+
+<p>It is an easy transition to pass from the consideration
+of European and other dormant, or extinct,
+volcanic regions to those of the British Isles,
+though the volcanic forces may have become in
+this latter instance quiescent for a somewhat longer
+period. In all the cases we have been considering,
+whether those of Central Italy, of the Rhine and
+Moselle, of Auvergne, or of Syria and Arabia, the
+cones and craters of eruption are generally present
+entire, or but slightly modified in form and size by
+the effects of time. But in the case of the Tertiary
+volcanic districts of the British Isles this is not so.
+On the contrary, these more prominent features of
+vulcanicity over the surface of the ground have been
+removed by the agents of denudation, and our
+observations are confined to the phenomena presented
+by extensive sheets of lava and beds of ash,
+or the stumps and necks of former vents of eruption,
+<span class="pagenum"><a name="Page_155" id="Page_155">[Pg 155]</a></span>together with dykes of trap by which the plateau-lavas
+are everywhere traversed or intersected.</p>
+
+<p>The volcanic region of the British Isles extends at
+intervals from the North-east of Ireland through the
+Island of Mull and adjoining districts on the mainland
+of Morvern and Ardnamurchan into the Isle of Skye,
+and comprises several smaller islets; the whole being
+included in the general name of the Inner Hebrides.
+It is doubtful if the volcanic lavas of Co. Antrim were
+ever physically connected with those of the west of
+Scotland, though they may be considered as contemporary
+with them; and in all cases the existing
+tracts of volcanic rock are mere fragments of those
+originally formed by the extrusion of lavas from
+vents of eruption. In addition to these, there are
+large areas of volcanic rock overspread by the waters
+of the ocean.</p>
+
+<p>(<i>a.</i>) <i>Geological Age.</i>&mdash;The British volcanic eruptions
+now under consideration are all later than the Cretaceous
+period. Throughout Antrim, and in parts of
+Mull, the lavas are found resting on highly eroded
+faces either of the Upper Chalk (<a href="#FIGURE_27">Fig. 27</a>), or, where it
+has been altogether denuded away, on still older Mesozoic
+strata. From the relations of the basaltic sheets of
+Antrim to the Upper Chalk, it is clear that the latter
+formation, after its deposition beneath the waters of
+the Cretaceous seas, was elevated into dry land and
+exposed to a long period of subaërial erosion before
+the first sheets of lava invaded the surface of the
+ground. We are, therefore, tolerably safe in considering
+the first eruptions to belong to the Tertiary
+period; but the evidence, derived as it is exclusively
+from plant remains, is somewhat conflicting as to the
+precise epoch to which the lavas and beds of tuff
+<span class="pagenum"><a name="Page_156" id="Page_156">[Pg 156]</a></span>containing the plant-remains are to be referred. The
+probabilities appear to be that they are of Miocene
+age; and if so, the trachytic lavas, which in Antrim
+are older than those containing plants, may be referred
+to a still earlier epoch&mdash;namely, that of the Eocene.<a name="FNanchor_1_130" id="FNanchor_1_130"></a><a href="#Footnote_1_130" class="fnanchor">[1]</a>
+As plant remains are not very distinctive, the question
+regarding the exact time of the first volcanic eruptions
+will probably remain for ever undecided; but
+we are not likely to be much in error if we consider
+the entire volcanic period to range from the close of
+the Eocene to that of the Miocene; by far the greater
+mass of the volcanic rocks being referable to the
+latter epoch.</p>
+
+<p>In describing the British volcanic districts it will be
+most convenient to deal with them in three divisions&mdash;viz.,
+those of Antrim, Mull, and Skye, commencing
+with Antrim.<a name="FNanchor_2_131" id="FNanchor_2_131"></a><a href="#Footnote_2_131" class="fnanchor">[2]</a></p>
+
+<p>(<i>b.</i>) <i>Volcanic Area.</i>&mdash;The great sheets of basalt and
+other volcanic products of the North-east of Ireland
+overspread almost the whole of the County Antrim,
+and adjoining districts of Londonderry and Tyrone,
+breaking off in a fine mural escarpment along the
+<span class="pagenum"><a name="Page_157" id="Page_157">[Pg 157]</a></span>northern shore of Belfast Lough and the sea coast
+throughout the whole of its range from Larne
+Harbour to Lough Foyle; the only direction in which
+these features subside into the general level of the
+country being around the shores of Lough Neagh.
+Several outliers of the volcanic sheets are to be found
+at intervals around the great central plateau; such as
+those of Rathlin Island, Island Magee, and Scrabo
+Hill in Co. Down. The area of the basaltic plateau
+may be roughly estimated at 2,000 square miles.</p>
+
+<div class="figcenter">
+<a name="FIGURE_27"></a>
+<a href="images/figure27full.jpg">
+  <img src="images/figure27.jpg" alt="The White Rocks" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 27.</span>&mdash;"The White Rocks," Portrush, Co. Antrim, showing the plateau-basalt resting on an eroded surface of the Upper
+Chalk, with bands of flint.&mdash;(From a photograph.)
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_158" id="Page_158">[Pg 158]</a></span></p><p>The truncated edges of this marginal escarpment
+rising to levels of 1,000 to 1,260 feet, as in the case of
+Benevenagh in Co. Derry, and 1,825 feet at Mullaghmore,
+attest an originally greatly more extended
+range of the basaltic sheets; and it is not improbable
+that at the close of the Miocene epoch they extended
+right across the present estuary of Lough Foyle to
+the flanks of the mountains of Inishowen in Donegal
+in one direction, and to those of Slieve Croob in the
+other. In the direction of Scotland the promontories
+of Kintyre and Islay doubtless formed a part of the
+original margin. Throughout this vast area the volcanic
+lavas rest on an exceedingly varied rocky floor,
+both as regards composition and geological age. (See
+<a href="#FIGURE_28">Fig. 28</a>.) Throughout the central, southern, eastern,
+and northern parts of their extent, the Chalk formation
+may be considered to form this floor; but in the
+direction of Armagh and Tyrone, towards the southwestern
+margin, the basaltic sheets are found resting
+indiscriminately on Silurian, Carboniferous, and
+Triassic strata. The general relations of the plateau-basalts
+to the underlying formations show, that at the
+close of the Cretaceous period there had been considerable
+terrestrial disturbances and great subaërial
+<span class="pagenum"><a name="Page_159" id="Page_159">[Pg 159]</a></span>denudation, resulting in some cases in the complete
+destruction of the whole of the Cretaceous strata,
+before the lava floods were poured out; owing to
+which, these latter are found resting on formations of
+older date than the Cretaceous.<a name="FNanchor_3_132" id="FNanchor_3_132"></a><a href="#Footnote_3_132" class="fnanchor">[3]</a></p>
+
+<div class="figcenter">
+<a name="FIGURE_28"></a>
+<a href="images/figure28full.jpg">
+  <img src="images/figure28.jpg" alt="Volcanic plateau of Antrim" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 28.</span>&mdash;Section across the volcanic plateau of Antrim, from the
+Highlands of Inishowen, Co. Donegal, on the N.W., to Belfast Lough
+on the S.E., to show the relations of the volcanic rocks to the older
+formations.&mdash;B. Basaltic sheets breaking off in high escarpments; T.
+Trachyte porphyry of Tardree mountain rising from below the newer
+plateau-basalts; C. Upper Chalk with flints; N.R. New Red marl and
+sandstone (Trias); M. Metamorphic beds of quartzite, various schists
+and crystalline limestone; F. Large fault.
+</td></tr>
+</table>
+</div>
+
+<div class="footnote"><p><a name="Footnote_1_130" id="Footnote_1_130"></a><a href="#FNanchor_1_130"><span class="label">[1]</span></a> Mr. J. Starkie Gardner, from a recent comparison of the plant-remains
+of Antrim and Mull, concludes that "that they might belong to
+any age between the beginning and the end of the warmer Eocene
+period; and that they cannot be of earlier, and are unlikely to be of
+later, date."&mdash;<i>Trans. Palæont. Soc.</i>, vol. xxxvii. (1883).</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_131" id="Footnote_2_131"></a><a href="#FNanchor_2_131"><span class="label">[2]</span></a> Having dealt with this district rather fully in <i>The Physical Geology
+and Geography of Ireland</i> (Edit. 1891, p. 81), and also in my Presidential
+Address (Section C.) at the meeting of the British Association,
+1874, a brief review of the subject will be sufficient here, the reader
+being referred to the former treatises for fuller details. The following
+should also be consulted: Gen. Portlock, <i>Geology of Londonderry and
+Tyrone</i> (1843); Sir A. Geikie, "History of Volcanic Action during the
+Tertiary Period in the British Isles," <i>Trans. Roy. Soc. Edinburgh</i>,
+1888; and the <i>Descriptive Memoirs</i> of the Geological Survey relating
+to this tract of country.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_132" id="Footnote_3_132"></a><a href="#FNanchor_3_132"><span class="label">[3]</span></a> Owing to the superposition of the basaltic masses on beds of chalk
+throughout a long line of coast, we are presented with the curious
+spectacle of the whitest rocks in nature overlain by the blackest, as may
+be seen in the cliffs at Larne, Glenarm, Kinbane and Portrush. (See
+<a href="#FIGURE_27">Fig. 27</a>.)</p></div>
+<p><span class="pagenum"><a name="Page_160" id="Page_160">[Pg 160]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_IV_CHAPTER_II" id="PART_IV_CHAPTER_II"></a>CHAPTER II.
+<br /><br />
+SUCCESSION OF VOLCANIC ERUPTIONS.</h2>
+
+
+<p>(<i>c.</i>) <i>First Stage.</i>&mdash;The earliest eruptions of lava in
+the North-east of Ireland belonged to the highly acid
+varieties, consisting of quartz-trachyte with tridymite.<a name="FNanchor_1_133" id="FNanchor_1_133"></a><a href="#Footnote_1_133" class="fnanchor">[1]</a>
+This rock rises to the surface at Tardree and Brown
+Dod hills and Templepatrick. It consists of a light-greyish
+felsitic paste enclosing grains of smoke-quartz,
+crystals of sanidine, plagioclase and biotite,
+with a little magnetite and apatite. It is a rock
+of peculiar interest from the fact that it is almost
+unique in the British Islands, and has its petrological
+counterpart rather amongst the volcanic hills of the
+Siebengebirge than elsewhere. It is generally consolidated
+with the columnar structure.</p>
+
+<p><span class="pagenum"><a name="Page_161" id="Page_161">[Pg 161]</a></span></p>
+
+<div class="figcenter">
+<a name="FIGURE_29">
+  <img src="images/figure29.jpg" alt="Quarry at Templepatrick" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 29.</span>&mdash;Part of the section shown in the quarry at Templepatrick,
+showing the superposition of the basalt (<i>d</i>) to the trachyte (<i>b</i>), with the
+intervening bed of flint gravel (<i>c</i>). All these rocks are seen to rest
+upon an eroded surface of the Chalk formation (<i>a</i>).
+</td></tr>
+</table>
+</div>
+
+<p>The trachyte appears to have been extruded from
+one or more vents in a viscous condition, the principal
+vent being probably situated under Tardree mountain,
+where the rock occurs in greatest mass, and it probably
+arose as a dome-shaped mass, with a somewhat
+extended margin, above the floor of Chalk which formed
+the surface of the ground.<a name="FNanchor_2_134" id="FNanchor_2_134"></a><a href="#Footnote_2_134" class="fnanchor">[2]</a> (<a href="#FIGURE_27">Fig. 27</a>.) At Templepatrick
+the columnar trachyte may be observed
+resting on the Chalk, or upon a layer of flint gravel
+interposed between the two rocks, and which has been
+thrust out of position by a later intrusion of basalt
+coming in from the side.<a name="FNanchor_3_135" id="FNanchor_3_135"></a><a href="#Footnote_3_135" class="fnanchor">[3]</a> It is to be observed,
+however, that the trachytic lavas nowhere appear
+cropping out along with the sheets of basalt around
+the escarpments overlooking the sea, or inland;
+showing that they did not spread very far from their
+<span class="pagenum"><a name="Page_162" id="Page_162">[Pg 162]</a></span>vents of eruption; a fact illustrating the lower
+viscosity, or fluidity, of the acid lavas as compared
+with those of the basic type.</p>
+
+<p>(<i>d.</i>) <i>Second Stage.</i>&mdash;After an interval, probably of
+long duration, a second eruption of volcanic matter
+took place over the entire area; but now the acid lavas
+of the first stage are replaced by basic lavas. Now,
+for the first time, vast masses of basalt and dolerite
+are extruded both from vents of eruption and fissures;
+and, owing to their extreme viscosity, spread themselves
+far and wide until they reach the margin of
+some uprising ground of old Palæozoic or Metamorphic
+rocks by which the volcanic plain is almost
+surrounded. The great lava sheets thus produced
+are generally more or less amorphous, vesicular and
+amygdaloidal, often exhibiting the globular concentric
+structure, and weathering rapidly to a kind of ferruginous
+sand or clay under the influence of the atmosphere.
+Successive extrusions of these lavas produce
+successive beds, which are piled one over the other in
+some places to a depth of 600 feet; and at the close
+of the stage, when the volcanic forces had for the
+time exhausted themselves, the whole of the North-east
+of Ireland must have presented an aspect not
+unlike that of one of those great tracts of similar
+lava in the region of Idaho and the Snake River in
+Western America, described in a previous chapter.</p>
+
+<p>(<i>e.</i>) <i>Third Stage (Inter-volcanic).</i>&mdash;The third stage
+may be described as inter-volcanic. Owing to the
+formation of a basin, probably not deep, and with
+gently sloping sides, a large lake was formed over
+the centre of the area above described. Its floor was
+basalt, and the streams from the surrounding uplands
+carried down leaves and stems of trees, strewing them
+<span class="pagenum"><a name="Page_163" id="Page_163">[Pg 163]</a></span>over its bed. Occasionally eruptions of ash took place
+from small vents, forming the ash-beds with plants
+found at Ballypallidy, Glenarm, and along the coast
+as at Carrick-a-raide. The streams also brought
+down sand and gravel from the uprising domes of
+trachyte, and deposited them over the lake-bed along
+with the erupted ashes.<a name="FNanchor_4_136" id="FNanchor_4_136"></a><a href="#Footnote_4_136" class="fnanchor">[4]</a> The epoch we are now
+referring to was one of economic importance; as,
+towards its close, there was an extensive deposition
+of pisolitic iron-ore over the floor of the lake, sometimes
+to the depth of two or three feet. This ore has
+been extensively worked in recent years.</p>
+
+<div class="figcenter">
+<a name="FIGURE_30"></a>
+<a href="images/figure30full.jpg">
+  <img src="images/figure30.jpg" alt="Cliffs above the Giant's Causeway" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 30.</span>&mdash;Cliff section above the Giant's Causeway, coast of Co. Antrim, showing successive tiers of basaltic
+lava, with intervening bands of bole.
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_164" id="Page_164">[Pg 164]</a></span></p><p>(<i>f.</i>) <i>Fourth Stage (Volcanic).</i>&mdash;The last stage described
+was brought to a termination by a second
+outburst of basic lavas on a scale probably even
+grander than the preceding. These lavas consisting
+of basalt and dolerite, with their varieties, and extruded
+from vents and fissures, spread themselves in all
+directions over the pre-existing lake deposits or the
+older sheets of augitic lava, and probably entirely
+buried the trachytic hills. These later sheets solidified
+into more solid masses than those of the second
+stage. They form successive terraces with columnar
+structure, each terrace differing from that above and
+below it in the size and length of the columns, and
+separated by thin bands of "bole" (decomposed lava),
+often reddish in colour, clearly defining the limits of
+the successive lava-flows. Nowhere throughout the
+entire volcanic area are these successive terraces so
+finely laid open to view as along the north coast of
+Antrim, where the lofty mural cliffs, worn back into
+successive bays with intervening headlands by the
+<span class="pagenum"><a name="Page_165" id="Page_165">[Pg 165]</a></span>irresistible force of the Atlantic waves, present to the
+spectator a vertical section from 300 to 400 feet in
+height, in which the successive tiers of columnar
+basalt, separated by thin bands of bole, are seen to
+rise one above the other from the water's edge to the
+summit of the cliff, as shown in <a href="#FIGURE_30">Fig. 30</a>. Here, also,
+at the western extremity of the line of cliffs we find
+that remarkable group of vertical basaltic columns,
+stretching from the base of the cliff into the Atlantic,
+and known far and wide by the name of "The Giant's
+Causeway," the upper ends of the columns forming a
+tolerably level surface, gently sloping seawards, and
+having very much the aspect of an artificial tesselated
+pavement on a huge scale. A portion of the Causeway,
+with the cliff in the background, is shown in the
+figure (<a href="#FIGURE_31">Fig. 31</a>). The columns are remarkable for their
+symmetry, being generally hexagonal, though occasionally
+they are pentagons, and each column is
+horizontally traversed by joints of the ball-and-socket
+form, thus dividing them into distinct courses of
+natural masonry. These are very well shown in the
+accompanying view of the remarkable basaltic pillars
+known as "The Chimneys," which stand up from
+the margin of the headland adjoining the Causeway,
+monuments of past denudation, as they originally
+formed individuals amongst the group belonging
+to one of the terraces in the adjoining coast.<a name="FNanchor_5_137" id="FNanchor_5_137"></a><a href="#Footnote_5_137" class="fnanchor">[5]</a>
+(<a href="#FIGURE_32">Fig. 32</a>).</p>
+
+<div class="figcenter">
+<a name="FIGURE_31">
+  <img src="images/figure31.jpg" alt="The Giant's Causeway" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 31.</span>&mdash;The Giant's Causeway, formed of basaltic columns in a
+vertical position, and of pentagonal or hexagonal section; above the
+Causeway is seen a portion of the cliff composed of tiers of lava with
+intervening bands of bole, etc.&mdash;(From a photograph.)
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_166" id="Page_166">[Pg 166]</a></span></p>
+
+<div class="figcenter">
+<a name="FIGURE_32">
+  <img src="images/figure32.jpg" alt="The Chimneys" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 32.</span>&mdash;"The Chimneys," columns of basalt on slope of cliff overlooking
+the Atlantic, north coast of Co. Antrim. The horizontal segments,
+or cup-and-ball joints, of the columns are well shown in this
+figure. (From a photograph.)
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_167" id="Page_167">[Pg 167]</a></span></p><p>(<i>g.</i>) <i>Original Thickness of the Antrim Lavas.</i>&mdash;It
+is impossible to determine with certainty what may
+have been the original thickness of the accumulated
+sheets of basic lavas with their associated beds of ash
+and bole. The greatest known thickness of the lower
+zone of lavas is, as I have already stated, about 600
+feet. The intermediate beds of ash and bole sometimes
+attain a thickness of 40 feet, and the upper
+group of basalt about 400 feet; these together would
+constitute a series of over 1,000 feet in thickness. But
+this amount, great as it is, is undoubtedly below the
+original maximum, as the uppermost sheets have been
+removed by denuding agencies, we know not to what
+extent. Nor is it of any great importance. Sufficient
+remains to enable us to form a just conception
+of the magnitude both as regards thickness and extent
+of the erupted matter of the Miocene period over the
+North-east of Ireland and adjoining submerged tracts,
+and of the magnitude of the volcanic operations necessary
+for the production of such masses.</p>
+
+<p><span class="pagenum"><a name="Page_168" id="Page_168">[Pg 168]</a></span></p><p>(<i>h.</i>) <i>Volcanic Necks.</i>&mdash;As already remarked, no
+craters of eruption survive throughout the volcanic
+region of the North-east of Ireland, owing to the
+enormous extent of the denudation which this region
+has undergone since the Miocene Epoch; but the old
+"necks" of such craters&mdash;in other words, the pipes
+filled with either solid basalt, or basalt and ashes&mdash;are
+still to be found at intervals over the whole area.
+Owing to the greater solidity of the lava which filled
+up these "necks" over the plateau-basaltic sheets
+which surround them, they appear as bosses or hills
+rising above the general level of the ground. One of
+these bosses of highly columnar basalt occurs between
+Portrush and Bushmills, not far from Dunluce Castle,
+another at Scawt Hill, near Glenarm, and a third at
+Carmoney Hill above Belfast Lough. But by far
+the most prominent of these old solidified vents of
+eruption is that of Sleamish, a conspicuous mountain
+which rises above the general level of the plateau
+near Ballymena, and attains an elevation of 1,437 feet
+above the sea. Seen from the west, the mountain
+has the appearance of a round-topped cone; but on
+examination it is found to be in reality a huge dyke,
+breaking off abruptly towards the north-west, in which
+direction it reaches its greatest height, then sloping
+downwards towards the east. This form suggests
+that Sleamish is in reality one of the fissure-vents
+of eruption rather than the neck of an old volcano.
+The rock of which it is formed consists of exceedingly
+massive, coarsely-crystalline dolerite, rich in olivine,
+and divided into large quadrangular blocks by parallel
+joint planes. Its junction with the plateau-basalt
+from which it rises can nowhere be seen; but at the
+nearest point where the two rocks are traceable the
+<span class="pagenum"><a name="Page_169" id="Page_169">[Pg 169]</a></span>plateau-basalt appears to be somewhat indurated;
+breaking with a splintery fracture and a sharp ring
+under the hammer, suggesting that the lava of
+Sleamish had been extruded through the horizontal
+sheets, and had considerably indurated the portions in
+contact with, or in proximity to, it.<a name="FNanchor_6_138" id="FNanchor_6_138"></a><a href="#Footnote_6_138" class="fnanchor">[6]</a> Amongst the
+vents filled with ash and agglomerate, the most remarkable
+is that of Carrick-a-raide, near Ballycastle.
+It forms this rocky island and a portion of the adjoining
+coast, where the beds of ash are finely displayed;
+consisting of fragments and bombs of basalt, with
+pieces of chalk, flint, and peperino, which is irregularly
+bedded. These ash-beds attain a thickness of about
+120 feet just below the road to Ballycastle, but rapidly
+tail out in both directions from the locality of the
+vent. Just below the ash-beds, the white chalk with
+flints may be seen extending down into the sea-bed.
+Nowhere in Antrim is there such a display of volcanic
+ash and agglomerate as at this spot.<a name="FNanchor_7_139" id="FNanchor_7_139"></a><a href="#Footnote_7_139" class="fnanchor">[7]</a></p>
+
+<p>(<i>i.</i>) <i>Dykes: Conditions under which they were
+Erupted.</i>&mdash;No one can visit the geological sections
+in Co. Antrim and the adjoining districts of Down,
+Armagh, Derry, and Tyrone, without being struck by
+the great number and variety of the igneous dykes
+by which the rocks are traversed. The great majority
+of these dykes are basaltic, and they are found traversing
+all the formations, including the Cretaceous and
+Tertiary basaltic sheets. The Carlingford and Mourne
+Mountains are seamed with such dykes, and they are
+<span class="pagenum"><a name="Page_170" id="Page_170">[Pg 170]</a></span>splendidly laid open to view along the coast south
+of Newcastle in Co. Down, as also along the Antrim
+coast from Belfast to Larne. The fine old castle of
+Carrickfergus has its foundations on one of those dyke-like
+intrusions, but one of greater size than ordinary.
+All the dykes here referred to are not, however, of
+the same age, as is conclusively proved by sections
+amongst the Mourne Mountains where cliffs of Lower
+Silurian strata, superimposed on the intrusive granite
+of the district, exhibit two sets of basaltic dykes&mdash;one
+(the older) abruptly terminated at the granite margin,
+the other and newer penetrating the granite and Silurian
+rocks alike. It is not improbable that the older
+dykes belong to the Carboniferous or Permian age,
+while the newer are with equal probability of Tertiary
+age. Sir A. Geikie has shown that the Tertiary dykes
+of the North of Ireland are representatives of others
+occurring at intervals over the North of England,
+and Central and Western Scotland, all pointing towards
+the central region of volcanic activity; or in a parallel
+direction thereto, approximating to the N.W. in
+Ireland, the Island of Islay, and East Argyleshire,
+but in the centre of Scotland generally ranging from
+east to west.<a name="FNanchor_8_140" id="FNanchor_8_140"></a><a href="#Footnote_8_140" class="fnanchor">[8]</a> The area affected by the dykes of undoubted
+Tertiary age Geikie estimates at no less than
+40,000 square miles&mdash;a territory greater than either
+Scotland or Ireland, and equal to more than a third
+of the total land-surface of the British Isles;<a name="FNanchor_9_141" id="FNanchor_9_141"></a><a href="#Footnote_9_141" class="fnanchor">[9]</a> and he
+regards them as posterior "to the rest of the geological
+structures of the regions which they traverse."
+<span class="pagenum"><a name="Page_171" id="Page_171">[Pg 171]</a></span>It is clear that the dykes referred to belong to one
+great system of eruption or intrusion; and they may
+be regarded as the manifestation of the final effort of
+internal forces over this region of the British Isles.
+They testify to the existence of a continuous <i>magma</i>
+(or shell) of augitic lava beneath the crust; and as
+the aggregate horizontal extent of all these dykes, or
+of the fissures which they fill, must be very considerable,
+it is clear that the crust through which they
+have been extruded has received an accession of
+horizontal space, and has been fissured by forces
+acting from beneath, as the late Mr. Hopkins, of
+Cambridge, had explained on mechanical grounds in
+his elaborate essay many years ago.<a name="FNanchor_10_142" id="FNanchor_10_142"></a><a href="#Footnote_10_142" class="fnanchor">[10]</a> This view
+occurred to myself when examining the region of the
+North-east of Ireland, but I was not then aware that it
+had been dealt with on mathematical principles by so
+eminent a mathematician. The bulging of the crust
+is a necessary consequence of the absence of plication
+of the strata due to the extrusion of this enormous
+quantity of molten lava; and the intrusion of
+thousands of dykes over the North-east of Ireland,
+unaccompanied by foldings of the strata, must have
+added a horizontal space of several thousand feet to
+that region.<a name="FNanchor_11_143" id="FNanchor_11_143"></a><a href="#Footnote_11_143" class="fnanchor">[11]</a></p>
+
+<div class="footnote"><p><a name="Footnote_1_133" id="Footnote_1_133"></a><a href="#FNanchor_1_133"><span class="label">[1]</span></a> A peculiar form of crystalline quartz first recognized in this rock by
+a distinguished German petrologist, the late Prof. A. von Lasaulx, who
+visited the district in 1876.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_134" id="Footnote_2_134"></a><a href="#FNanchor_2_134"><span class="label">[2]</span></a> Sir A. Geikie has disputed the correctness of the view, which I advocated
+as far back as 1874, that the trachytic lavas of Antrim are the earliest
+products of volcanic action; but at the time he wrote his paper on the
+volcanic history of these islands, it was not known that pebbles of this
+trachyte are largely distributed amongst the ash-beds which occur in the
+very midst of the overlying basaltic sheets, as I shall have to explain
+later on. This discovery puts the question at rest as regards the
+relations of the two sets of rocks.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_135" id="Footnote_3_135"></a><a href="#FNanchor_3_135"><span class="label">[3]</span></a> This remarkable section at the chalk quarries of Templepatrick the
+author has figured and described in the <i>Physical Geology and Geography
+of Ireland</i>, p. 99, 2nd edit. (1891), where the reader will find the subject
+discussed more fully than can be done here.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_136" id="Footnote_4_136"></a><a href="#FNanchor_4_136"><span class="label">[4]</span></a> These pebbles were first noticed by Mr. McHenry, of the Irish
+Geological Survey, in 1890.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_137" id="Footnote_5_137"></a><a href="#FNanchor_5_137"><span class="label">[5]</span></a> The vertical position of the columns of the Giant's Causeway is
+rather enigmatical. The Causeway cannot be a dyke, as has often been
+supposed, otherwise the columns would have been horizontal, <i>i.e.</i>, at
+right angles to the sides of the dyke. Mr. R. G. Symes, of the Geological
+Survey, has suggested that the Causeway columns have been
+vertically lowered between two lines of fault, and that originally they
+formed a portion of the tier of beautiful columns seen in the cliff above,
+and known as "The Organ."</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_138" id="Footnote_6_138"></a><a href="#FNanchor_6_138"><span class="label">[6]</span></a> Sleamish and several other of the Antrim vents are described by Sir
+A. Geikie in the monograph already referred to, <i>loc. cit.</i>, p. 101, <i>et seq.</i>
+Also in the <i>Expl. Memoirs of the Geological Survey of Ireland</i>.</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_139" id="Footnote_7_139"></a><a href="#FNanchor_7_139"><span class="label">[7]</span></a> A diagrammatised section of the Carrick-a-raide volcanic neck is
+given by Sir A. Geikie, <i>loc. cit.</i>, p. 105.</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_140" id="Footnote_8_140"></a><a href="#FNanchor_8_140"><span class="label">[8]</span></a> Geikie, <i>loc. cit.</i>, p. 29, <i>et seq.</i></p></div>
+
+<div class="footnote"><p><a name="Footnote_9_141" id="Footnote_9_141"></a><a href="#FNanchor_9_141"><span class="label">[9]</span></a> P. 32. The view that the crust of the earth has been horizontally
+extended by the intrusion of dykes is noticed by McCulloch in reference
+to the dykes of Skye.</p></div>
+
+<div class="footnote"><p><a name="Footnote_10_142" id="Footnote_10_142"></a><a href="#FNanchor_10_142"><span class="label">[10]</span></a> Hopkins, <i>Cambridge Phil. Trans.</i>, vol. vi. p. 1 (1836).</p></div>
+
+<div class="footnote"><p><a name="Footnote_11_143" id="Footnote_11_143"></a><a href="#FNanchor_11_143"><span class="label">[11]</span></a> As suggested in my Presidential Address to Section C. of the British
+Association at Belfast, 1874.</p></div>
+<p><span class="pagenum"><a name="Page_172" id="Page_172">[Pg 172]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_IV_CHAPTER_III" id="PART_IV_CHAPTER_III"></a>CHAPTER III.
+<br /><br />
+ISLAND OF MULL AND ADJOINING COAST.</h2>
+
+
+<p>The Island of Mull, with the adjoining districts of
+Morvern and Ardnamurchan, forms the more southern
+of the two chief centres of Tertiary volcanic eruptions
+in the West of Scotland, that of Skye being the more
+northern. These districts have been the subject of
+critical and detailed study by several geologists, from
+McCulloch down to the present day; and amongst
+the more recent, Sir Archibald Geikie and Professor
+Judd hold the chief place. Unfortunately, the interpretation
+of the volcanic phenomena by these two
+accomplished observers has led them to very different
+conclusions as regards several important points in the
+volcanic history of these groups of islands; as, for
+example, regarding the relative ages of the plateau-basalts
+and the acid rocks, such as the trachytes and
+granophyres; again as regards the presence of distinct
+centres of eruption; and also as regards the relations
+of the gabbros of Skye to the basaltic sheets. Such
+being the case, it would appear the height of rashness
+on the part of the writer, especially in the absence of
+a detailed examination of the sections over the whole
+region, to venture on a statement of opinion regarding
+the points at issue; and he must, therefore, content
+himself with a brief account of the phenomena as
+<span class="pagenum"><a name="Page_173" id="Page_173">[Pg 173]</a></span>gathered from a perusal of the writings of these and
+other observers,<a name="FNanchor_1_144" id="FNanchor_1_144"></a><a href="#Footnote_1_144" class="fnanchor">[1]</a> guided also to some extent by the
+analogous phenomena presented by the volcanic
+region of the North-east of Ireland.</p>
+
+<p>(<i>a.</i>) <i>General Features.</i>&mdash;As in the case of the
+Antrim district, the Island of Mull and adjoining
+tracts present us with the spectacle of a vast accumulation
+of basaltic lava-flows, piled layer upon layer,
+with intervening beds of bole and tuff, up to a thickness,
+according to Geikie, of about 3,500 feet. At the
+grand headland of Gribon, on the west coast, the
+basaltic sheets are seen to rise in one sheer sweep to
+a height of 1,600 feet, and then to stretch away with
+a slight easterly dip under Ben More at a distance of
+some eight miles. This mountain, the upper part of
+which is formed of beds of ashes, reaches an elevation
+of 3,169 feet, so that the accumulated thickness of the
+beds of basalt under the higher part of the mountain
+must be at least equal to the amount stated above&mdash;that
+is, twice as great as the representative masses of
+Antrim. The base of the volcanic series is seen at
+Carsaig and Gribon to rest on Cretaceous and
+Jurassic rocks, like those of Antrim; hence the
+Tertiary age is fully established by the evidence of
+superposition. This was further confirmed by the
+discovery by the Duke of Argyll,<a name="FNanchor_2_145" id="FNanchor_2_145"></a><a href="#Footnote_2_145" class="fnanchor">[2]</a> some years ago
+(1850), of bands of flint-gravel and tuff, with dicotyledonous
+leaves amongst the basalts of Ardtun Head.
+<span class="pagenum"><a name="Page_174" id="Page_174">[Pg 174]</a></span>The basement beds of tuff and gravel contain, besides
+pebbles of flint and chalk, others of sanidine trachyte,
+showing that highly acid lavas had been extruded
+and consolidated before the first eruption of the
+plateau-basalts; another point of analogy between the
+volcanic phenomenon of Antrim and the Inner Hebrides.
+These great sheets of augitic lava extend
+over the whole of the northern tract of Mull, the
+Isles of Ulva and Staffa, and for a distance of several
+miles inwards from the northern shore of the Sound
+of Mull, covering the wild moorlands of Morvern and
+Ardnamurchan, where they terminate in escarpments
+and outlying masses, indicating an originally much
+more extended range than at the present day. The
+summits of Ben More and its neighbouring height,
+Ben Buy, are formed of beds of ash and tuff. The
+volcanic plateau is, according to Judd, abruptly
+terminated along the southern side by a large vault,
+bringing the basalt in contact with Palæozoic rocks.<a name="FNanchor_3_146" id="FNanchor_3_146"></a><a href="#Footnote_3_146" class="fnanchor">[3]</a></p>
+
+<p>(<i>b.</i>) <i>Granophyres.</i>&mdash;The greater part of the tract
+lying to the south of Loch na Keal, which almost
+divides Mull into two islands, and extending southwards
+and eastwards to the shores of the Firth of
+Lorn and the Sound of Mull, is formed of a peculiar
+group of acid (or highly silicated) rocks, classed under
+the general term of "Granophyres." These rocks
+approach towards true granites in one direction, and
+through quartz-porphyry and felsite to rhyolite in
+another&mdash;probably depending upon the conditions of
+cooling and consolidation. In their mode of weathering
+and general appearance on a large scale, they
+present a marked contrast to the basic lavas with
+which they are in contact from the coast of L. na
+<span class="pagenum"><a name="Page_175" id="Page_175">[Pg 175]</a></span>Keal to that of L. Buy. The nature of this contact,
+whether indicating the priority of the granophyres to
+the plateau-basalts or otherwise, is a matter of dispute
+between the two observers above named; but the
+circumstantial account given by Sir A. Geikie,<a name="FNanchor_4_147" id="FNanchor_4_147"></a><a href="#Footnote_4_147" class="fnanchor">[4]</a> accompanied
+by drawings of special sections showing
+this contact, appears to prove that the granophyre is
+the newer of the two masses of volcanic rock, and
+that it has been intruded amongst the basaltic-lavas
+at a late period in the volcanic history of these islands.
+A copy of one of these sketches is here given (<a href="#FIGURE_33">Fig. 33</a>),
+according to which the felsite is shown to penetrate
+the basaltic sheets at Alt na Searmoin in Mull; other
+sections seen at Cruach Torr an Lochain, and on the
+south side of Beinn Fada, appear to lead to similar
+conclusions. These rocks are penetrated by numerous
+basaltic dykes.</p>
+
+<div class="figcenter">
+<a name="FIGURE_33">
+  <img src="images/figure33.jpg" alt="Alt na Searmoin" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 33.</span>&mdash;Section at Alt na Searmoin, Mull, to show the intrusion
+of felsite (or granophyre) (<i>b</i>) into basalt and dolerite (<i>a</i>) of the plateau-basalt
+series.&mdash;(Geikie.)
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_176" id="Page_176">[Pg 176]</a></span></p><p>(<i>c.</i>) <i>Representative Rocks of Mourne and Carlingford,
+Ireland.</i>&mdash;Assuming Sir A. Geikie's view to be
+correct, it is possible that we may have in the granite
+and quartz-porphyries of Mourne and Carlingford
+representatives of the granites, granophyres, and other
+acid rocks of the later period of Mull. The granite of
+Mourne is peculiar in structure, and differs from the
+ordinary type of that rock in which the silica forms
+the ground mass. In the case of the granite of the
+Mourne Mountains, the rock consists of a crystalline
+granular aggregate of orthoclase, albite, smoke-quartz,
+and mica; it is also full of drusy cavities, in which the
+various minerals crystallise out in very perfect form.
+As far as regards direct evidence, the age of this rock
+can only be stated to be post-Carboniferous, and earlier
+than certain Tertiary basaltic dykes by which it is
+traversed. The granophyres of Mull are traversed by
+similar dykes, which are representatives of the very
+latest stage of volcanic action in the British Islands.
+The author is therefore inclined to concur with Sir
+A. Geikie in assigning to the granite of the Mourne
+Mountains, and the representative felsitic rocks of the
+Carlingford Mountains, a Tertiary age&mdash;in which case
+the analogy between the volcanic phenomena of the
+Inner Hebrides and of the North-east of Ireland would
+seem to be complete.<a name="FNanchor_5_148" id="FNanchor_5_148"></a><a href="#Footnote_5_148" class="fnanchor">[5]</a></p>
+
+<div class="footnote"><p><a name="Footnote_1_144" id="Footnote_1_144"></a><a href="#FNanchor_1_144"><span class="label">[1]</span></a> Geikie, <i>Proc. Roy. Soc. Edinburgh</i> (1867); <i>Brit. Assoc. Rep.</i>
+(Dundee, 1867); "Tertiary Volcanic Rocks of the British Isles,"
+<i>Quart. Journ. Geol. Soc.</i>, vol. xxvii. p. 279; also, "History of Volcanic
+Action in British Isles," <i>Trans. Roy. Soc. Edin.</i> (1888); Judd, "On
+the Ancient Volcanoes of the Highlands," etc., <i>Quart. Journ. Geol. Soc.</i>,
+vol. xxx. p. 233; and <i>Volcanoes</i>, p. 139.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_145" id="Footnote_2_145"></a><a href="#FNanchor_2_145"><span class="label">[2]</span></a> <i>Brit. Assoc. Rep.</i> for 1850, p. 70.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_146" id="Footnote_3_146"></a><a href="#FNanchor_3_146"><span class="label">[3]</span></a> Judd, <i>Quart. Jour. Geol. Soc.</i>, vol. xxx. p. 242.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_147" id="Footnote_4_147"></a><a href="#FNanchor_4_147"><span class="label">[4]</span></a> <i>History of Volcanic Action, etc.</i>, <i>loc. cit.</i> p. 153, <i>et seq.</i> The
+"Granophyres" of Geikie come under the head of "Felsites," passing
+into "granite" in one direction and quartz-trachyte in another, according
+to Judd; the proportion of silica from 69 to 75 per cent.&mdash;<i>Quart.
+Jour. Geol. Soc.</i>, vol. xxx. p. 235.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_148" id="Footnote_5_148"></a><a href="#FNanchor_5_148"><span class="label">[5]</span></a> This view the author has expressed in a recent edition of <i>The
+Physical Geology of Ireland</i>, p. 177 (1891).</p></div>
+<p><span class="pagenum"><a name="Page_177" id="Page_177">[Pg 177]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_IV_CHAPTER_IV" id="PART_IV_CHAPTER_IV"></a>CHAPTER IV.
+<br /><br />
+ISLE OF SKYE.</h2>
+
+
+<p>This is the largest and most important of all the
+Tertiary volcanic districts, but owing to the extensive
+denudation to which, in common with other Tertiary
+volcanic regions of the British Isles, it has been subjected,
+its present limits are very restricted comparatively
+to its original extent. Not only is this evident
+from the manner in which the basaltic sheets terminate
+along the sea-coast in grand mural cliffs, as opposite
+"Macleod's Maidens," and at the entrance to Lough
+Bracadale on the western coast, but the evidence is,
+according to Sir A. Geikie, still more striking along the
+eastern coast; showing that the Jurassic, and other older
+rocks there visible, were originally buried deep under
+the basaltic sheets which have been stripped from off
+that part of the country. These great plateau-basalts
+occupy about three-fourths of the entire island along
+the western and northern areas, rising into terraced
+mountains over 2,000 feet in height, and are deeply
+furrowed by glens and arms of the sea, along which the
+general structure of the tableland is laid open, sometimes
+for leagues at a time.</p>
+
+<p>It is towards the south-eastern part of the island
+that the most interesting and important phenomena
+are centred; for here we meet with representatives
+<span class="pagenum"><a name="Page_178" id="Page_178">[Pg 178]</a></span>of the acid (or highly silicated) group of rocks, and of
+remarkable beds of gabbro, which have long attracted
+the attention of petrologists. These latter beds,
+throughout a considerable distance round the flanks
+of the Cuillin Hills, are interposed between the acid
+rocks and the plateau-basalts; but towards the north,
+on approaching Lough Sligahan, the acid rocks, consisting
+of granophyres, quartz-porphyries, and hornblendic-granitites,
+are in direct contact with the
+plateau-basalts; and, according to the very circumstantial
+account of Sir A. Geikie, are intrusive into
+them; not only sending veins into the basaltic sheets,
+but also producing a marked alteration in their structure
+where they approach the newer intrusive mass.
+Equally circumstantial is the same author's account of
+the relations of the granophyres to the gabbros,<a name="FNanchor_1_149" id="FNanchor_1_149"></a><a href="#Footnote_1_149" class="fnanchor">[1]</a> as seen
+at Meall Dearg and the western border of the Cuillin
+Hills&mdash;where the former rock may be seen to send
+numerous veins into the latter. Not only is this so,
+but the granophyre is frequently seen to truncate,
+and abruptly terminate some of the basaltic dykes by
+which the basic sheets are traversed&mdash;as in the neighbourhood
+of Beinn na Dubhaic. All these phenomena
+strongly remind us of the conditions of similar rocks
+amongst the mountains of Mourne and Carlingford in
+Ireland; where, at Barnaveve, the syenite (or hornblendic
+quartz-felsite) is seen to break through the
+masses of olivine gabbro, and send numerous veins
+into this latter rock.<a name="FNanchor_2_150" id="FNanchor_2_150"></a><a href="#Footnote_2_150" class="fnanchor">[2]</a></p>
+
+<p>The interpretation here briefly sketched differs
+<span class="pagenum"><a name="Page_179" id="Page_179">[Pg 179]</a></span>widely from that arrived at by Professor Judd. The
+granitoid masses of the Red Mountains (Beinn Dearg)
+and the neighbouring heights are, in his view, the
+roots of the great volcano from which were erupted
+the various lavas; the earlier eruptions producing
+the acid lavas, to be followed by the gabbros, and
+these by the plateau-basaltic sheets, which stretch
+away towards the north and west into several peninsulas.
+Thus he holds that "the rocks of basic composition
+were ejected subsequently to those of the
+acid variety," and appeals to various sections in confirmation
+of this view.<a name="FNanchor_3_151" id="FNanchor_3_151"></a><a href="#Footnote_3_151" class="fnanchor">[3]</a> To reconcile these views is
+at present impossible; but as the controversy between
+these two observers is probably not yet closed, there
+is room for hope that the true interpretation of the
+relations of these rocks to each other will ere long
+be fully established.</p>
+
+<div class="footnote"><p><a name="Footnote_1_149" id="Footnote_1_149"></a><a href="#FNanchor_1_149"><span class="label">[1]</span></a> Geikie, <i>loc. cit.</i>, p. 161, etc.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_150" id="Footnote_2_150"></a><a href="#FNanchor_2_150"><span class="label">[2]</span></a> <i>Physical Geology of Ireland</i>, 2nd edition, p. 174 (Fig. 21).
+Professor Judd has also come to the conclusion that the granite of
+Mourne is of Tertiary age, <i>Quart. Jour. Geol. Soc.</i>, vol. xxx. p. 275.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_151" id="Footnote_3_151"></a><a href="#FNanchor_3_151"><span class="label">[3]</span></a> Judd, <i>loc. cit.</i>, p. 254.</p></div>
+<p><span class="pagenum"><a name="Page_180" id="Page_180">[Pg 180]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_IV_CHAPTER_V" id="PART_IV_CHAPTER_V"></a>CHAPTER V.
+<br /><br />
+THE SCUIR OF EIGG.</h2>
+
+
+<p>Amongst the more remarkable of the smaller islets
+are those of Eigg, Rum, Canna, and Muck, lying between
+Mull on the south and Skye on the north, and
+undoubtedly at one time physically connected together.
+The Island of Eigg is especially remarkable
+for the fact, as stated by Geikie, that here we have
+the one solitary case of "a true superficial stream of
+acid lava&mdash;that of the Scuir of Eigg."<a name="FNanchor_1_152" id="FNanchor_1_152"></a><a href="#Footnote_1_152" class="fnanchor">[1]</a> (<a href="#FIGURE_34">Fig. 34</a>.)
+This forms a sinuous ridge, composed of pitchstone
+of several kinds, of over two miles in length, rising
+from the midst of a tableland of bedded basalt and
+tuff to a height of 1,289 feet above the ocean; the
+plateau-basalt is traversed by basaltic dykes, ranging
+in a N.W.-S.E. direction. But what is specially remarkable
+is the evidence afforded by an examination
+of the course of the Scuir, that it follows the channel
+of an ancient river-valley, which has been hollowed
+out in the surface of the plateau. The course of this
+channel is indicated by the presence of a deposit of
+river-gravel, which in some places forms a sort of
+cushion between the base of the Scuir and the side of
+the channel. Over this gravel-bed the viscous pitchstone-lava
+appears to have flowed, taking possession
+<span class="pagenum"><a name="Page_181" id="Page_181">[Pg 181]</a></span>of the river-channel, and also of the beds of several
+small tributary streams which flowed into the channel
+of the Scuir. The recent date of the pitchstone forming
+this remarkable mural ridge, once occupying the bed of
+a river-channel, is shown by the fact that the basaltic
+dykes which traverse the plateau-basalts are truncated
+by the river-gravel, which is, therefore, more recent;
+and, as we have seen, the pitchstone stream is more
+recent than the river-gravel. But at the time when
+this last volcanic eruption took place, the physical
+geography of the whole region must have been very
+different from that of the present time. From the
+character and composition of the pebbles in the old
+river-bed, amongst which are Cambrian sandstone,
+quartzite, clay-slate, and white Jurassic limestone,
+Sir A. Geikie concludes that when the river was
+flowing, the island must have been connected with
+the mainland to the east where the parent masses
+of these pebbles are found.</p>
+
+<div class="figcenter">
+<a name="FIGURE_34">
+  <img src="images/figure34.jpg" alt="Scuir of Eigg" style="margin-left:36px;" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 34.</span>&mdash;View of the Scuir of Eigg from the east. The lower
+portion of the mountain is formed of bedded basalt, or dolerite with
+numerous dykes and veins of basalt, felstone, and pitchstone; the upper
+cliff, or Scuir, is composed of pitchstone of newer age, the remnant of a
+lava flow which once filled a river channel in the basaltic sheets. A
+dyke, or sheet, of porphyry is seen to be interposed between the Scuir
+and the basaltic sheets.&mdash;(After Geikie.)
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_182" id="Page_182">[Pg 182]</a></span></p><p><i>Effects of Denudation.</i>&mdash;The position of the Scuir
+of Eigg and its relations to the basaltic sheets show
+the enormous amount of denudation which these
+latter have undergone since the stream of pitchstone-lava
+filled the old river channel. The walls, or banks,
+of the channel have been denuded away, thus converting
+the pitchstone casting into a projecting wall
+of rock. That it originally extended outwards into
+the ocean to a far greater distance than at present is
+evident from the abruptly truncated face of the cliff;
+and yet this remarkable volcanic mass seems to have
+been, perhaps, the most recent exhibition of volcanic
+action to be found in the British Isles. It is perhaps,
+on this account, the most striking of the numerous
+examples exhibited throughout the West of Scotland
+and the North-east of Ireland of the enormous amount
+of denudation to which these districts have been subjected
+since the extinction of the volcanic fires; and
+this at a period to which we cannot assign a date
+more ancient than that of the Pliocene. Yet, let us
+consider for a moment to what physical vicissitudes
+these districts have been subjected since that epoch.
+Assuming, as we may with confidence, that the volcanic
+eruptions were subaërial, and that the tracts
+covered by the plateau-basalts were in the condition
+of dry land when the eruptions commenced, in this
+<span class="pagenum"><a name="Page_183" id="Page_183">[Pg 183]</a></span>condition they continued in the main throughout the
+period of volcanic activity. But the eruptions had
+scarcely ceased, and the lava floods and dykes become
+consolidated, before the succeeding glacial epoch
+set in; when the snows and glaciers of the Scottish
+Highlands gradually descending from their original
+mountain heights, and spreading outwards in all
+directions, ultimately enveloped the whole of the
+region we are now considering until it was entirely
+concealed beneath a mantle of ice moving slowly,
+but irresistibly, outwards towards the Atlantic, crossing
+the deep channels, such as the Sound of Mull and
+the Minch, climbing up the sides of opposing rocks
+and islands until even the Outer Hebrides and the
+North-east of Ireland were covered by one vast
+mantle of ice and snow. The movement of such a
+body of ice over the land must have been attended
+with a large amount of abrasion of the rocky floor;
+nor have the evidences of that abrasion entirely disappeared
+even at the present day. We still detect
+the grooves and scorings on the rock-surfaces where
+they have been protected by a coating of boulder
+clay; and we still find the surface strewn with the
+blocks and <i>débris</i> of that mighty ice-flood.</p>
+
+<p>But whatever may have been the amount of erosion
+caused by the great ice-sheet, it was chiefly confined
+to the more or less horizontal surface-planes. Erosion
+of another kind was to succeed, and to produce more
+lasting effects on the configuration of the surface. On
+the disappearance of the ice-sheet, an epoch characterised
+by milder conditions of climate set in. This
+was accompanied by subsidence and submersion of
+large tracts of the land during the Interglacial stage;
+so that the sea rose to heights of several hundred feet
+<span class="pagenum"><a name="Page_184" id="Page_184">[Pg 184]</a></span>above the present level, and has left behind stratified
+gravels with shells at these elevations in protected
+places. During this period of depression and of subsequent
+re-emergence the wave-action of the Atlantic
+waters must have told severely on the coast and islands,
+wearing them into cliffs and escarpments, furrowing
+out channels and levelling obstructions. Such action
+has gone on down to the present day. The North-west
+of Scotland and of Ireland has been subjected
+throughout a very lengthened period to the wear and
+tear of the Atlantic billows. In the case of the former,
+the remarkable breakwater which nature has thrown
+athwart the North-west Highlands in the direction of
+the waves, forming the chain of islands constituting
+the Outer Hebrides, and composed of very tough
+Archæan gneiss and schist, has done much to retard the
+inroads which the waves might otherwise have made
+on the Isle of Skye; while Coll and Tiree, composed
+of similar materials, have acted with similar beneficent
+effect for Mull and the adjoining coasts. But such is
+the tremendous power of the Atlantic billows when
+impelled by westerly winds, that to their agency must
+be mainly attributed the small size of the volcanic
+land-surfaces as compared with their original extent,
+and the formation of those grand headlands which
+are presented by the igneous masses of Skye, Ardnamurchan,
+and Mull towards the west. Rain and river
+action, supplemented by that of glaciers, have also
+had a share in eroding channels and wearing down
+the upper surface of the ground, with the result we at
+present behold in the wild and broken scenery of the
+Inner Hebrides and adjoining coast.</p>
+
+<div class="footnote"><p><a name="Footnote_1_152" id="Footnote_1_152"></a><a href="#FNanchor_1_152"><span class="label">[1]</span></a> Geikie, <i>loc. cit.</i>, p. 178; also <i>Quart. Jour. Geol. Soc.</i>, vol. xxvii.
+p. 303.</p></div>
+<p><span class="pagenum"><a name="Page_185" id="Page_185">[Pg 185]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_IV_CHAPTER_VI" id="PART_IV_CHAPTER_VI"></a>CHAPTER VI.
+<br /><br />
+ISLE OF STAFFA.</h2>
+
+
+<p>Reference has been made to this remarkable island
+in a former page, but some more extended notice is
+desirable before leaving the region of the Inner
+Hebrides. Along with the islands of Pladda, Treshnish,
+and Blackmore, Staffa is one of the outlying
+volcanic islands of the group, being distant about six
+miles from the coast of Mull, and indicates the minimum
+distance to which the plateau-basaltic sheets
+originally extended in the direction of the old marginal
+lands of Tiree and Coll. The island consists of successive
+sheets of bedded basaltic lava, with partings
+of tuff, one of which of considerable thickness is shown
+to lie at the base of the cliff on the south-west side of
+the island.<a name="FNanchor_1_153" id="FNanchor_1_153"></a><a href="#Footnote_1_153" class="fnanchor">[1]</a> The successive lava-sheets present great
+varieties of structure, like those on the north coast of
+Antrim; some being amorphous, others columnar,
+with either straight or bent columns. The lava-sheet
+out of which Fingal's Cave is excavated consists of
+vertical prisms, beautifully formed, and surmounted
+by an amorphous mass of the same material. At the
+entrance of the Boat Cave we have a somewhat similar
+<span class="pagenum"><a name="Page_186" id="Page_186">[Pg 186]</a></span>arrangement of the columns;<a name="FNanchor_2_154" id="FNanchor_2_154"></a><a href="#Footnote_2_154" class="fnanchor">[2]</a> but at the Clam-shell
+Cave the prisms are curved, indicating some movement
+in the viscous mass before they had been fully
+consolidated.</p>
+
+<p>Fingal's Cave is called after the celebrated prince
+of Morvern (or Morven), a province of ancient Caledonia.
+He is supposed to have been the father of
+Ossian, the Celtic bard rendered famous by Macpherson.
+The cave, one of many which pierce the coast-cliffs
+of Western Scotland, is 227 feet in length,
+166 feet in height, and 40 feet in width. On all sides
+regular columns of basalt, some entire, others broken,
+rise out of the water and support the roof. The cave
+is only accessible in calm weather.</p>
+
+<div class="footnote"><p><a name="Footnote_1_153" id="Footnote_1_153"></a><a href="#FNanchor_1_153"><span class="label">[1]</span></a> A drawing of this cliff is given by Geikie in the <i>Manual of Geology</i>
+(Jukes and Geikie), 3rd edition, p. 277.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_154" id="Footnote_2_154"></a><a href="#FNanchor_2_154"><span class="label">[2]</span></a> Prestwich, <i>Geology</i>, vol. i. p. 281, where a view of this cave is
+given.</p></div>
+<p><span class="pagenum"><a name="Page_187" id="Page_187">[Pg 187]</a></span></p>
+
+
+<hr class="major" />
+<h1><a name="PART_V" id="PART_V"></a>PART V.
+<br /><br />
+PRE-TERTIARY VOLCANIC ROCKS.</h1>
+
+
+
+<hr class="major" />
+<h2><a name="PART_V_CHAPTER_I" id="PART_V_CHAPTER_I"></a>CHAPTER I.
+<br /><br />
+THE DECCAN TRAP-SERIES OF INDIA.</h2>
+
+
+<p>The great outpourings of augitic lava of Tertiary and
+recent times which we have been considering appear
+to have been anticipated in several parts of the world,
+more especially in Peninsular India and in Africa,
+and it is desirable that we should devote a few pages
+to the description of these remarkable volcanic formations,
+as they resemble, both in their mode of
+occurrence and general structure, some of the great
+lava-floods of a more recent period we have been considering.
+Of the districts to be described, the first
+which claims our notice is the Deccan.</p>
+
+<p>(<i>a.</i>) <i>Extent of the Volcanic Plateau.</i>&mdash;The volcanic
+plateau of the Deccan stretches from the borders of
+the Western Ghats and the sea-coast near Bombay
+inland to Amarantak, at the head of the Narbudda
+River (long. 82° E.), and from Belgaum (lat. 15° 31' N.)
+to near Goona (lat. 24° 30'). The vast area thus
+circumscribed is far from representing the original
+extent of the tract overspread by the lava-floods, as
+outlying fragments of these lavas are found as far
+east as long. 84° E. in one direction, and at Kattiwar
+<span class="pagenum"><a name="Page_188" id="Page_188">[Pg 188]</a></span>and Cutch in another. The present area, however, is
+estimated to be not less than 200,000 square miles.<a name="FNanchor_1_155" id="FNanchor_1_155"></a><a href="#Footnote_1_155" class="fnanchor">[1]</a></p>
+
+<p>(<i>b.</i>) <i>Nature and Thickness of the Lava-flows.</i>&mdash;This
+tract is overspread almost continuously by sheets of
+basaltic lava, with occasional bands of fresh-water strata
+containing numerous shells, figured and described by
+Hislop, and believed by him to be of Lower Eocene
+age. The lava-sheets vary considerably in character,
+ranging from finest compact basalt to coarsely
+crystalline dolerite, in which olivine is abundant.
+The columnar structure is not prevalent, the rock
+being either amorphous, or weathering into concentric
+shells. Volcanic ash, or bole, is frequently found
+separating the different lava-flows; and in the upper
+amygdaloidal sheets numerous secondary minerals are
+found, such as quartz, agate and jasper, stilbite and
+chlorite. The total thickness of the whole series,
+where complete, is about 6,000 feet, divided as follows:</p>
+
+<div class="center">
+<table border="0" cellpadding="4" cellspacing="0" summary="">
+<tr>
+<td align="left">1. Upper trap; with ash and inter-trappean beds</td>
+<td align="right">1,500</td>
+<td align="center">feet</td>
+</tr>
+<tr>
+<td align="left">2. Middle trap; sheets of basalt and ash</td>
+<td align="right">4,000</td>
+<td align="center">"</td>
+</tr>
+<tr>
+<td align="left">3. Lower trap; basalt with inter-trappean beds</td>
+<td align="right" style="border-bottom:1px solid black;">500</td>
+<td align="center" style="border-bottom:1px solid black;">"</td>
+</tr>
+<tr>
+<td align="left"></td>
+<td align="right" style="border-bottom:4px double black;">6,000</td>
+<td align="center" style="border-bottom:4px double black;">"</td>
+</tr>
+</table>
+</div>
+
+<p>Throughout the region here described these great
+sheets of volcanic rock are everywhere approximately
+horizontal, and constitute a table-land of 3,000 to
+4,000 feet in elevation, breaking off in terraced escarpments,
+and penetrated by deep river-valleys, of which
+the Narbudda is the most important. The foundation
+<span class="pagenum"><a name="Page_189" id="Page_189">[Pg 189]</a></span>rock is sometimes metamorphic schist, or gneiss,
+at other times sandstone referred by Hislop to
+Jurassic age; and in no single instance has a volcanic
+crater or focus of eruption been observed. But outside
+the central trappean area volcanic foci are numerous,
+as in Cutch, the Rajhipla Hills and the Lower Narbudda
+valley. The original excessive fluidity of the
+Deccan trap is proved by the remarkable horizontality
+of the beds over large areas, and the extensive
+regions covered by very thin sheets of basalt or dolerite.</p>
+
+<p>(<i>c.</i>) <i>Geological Age.</i>&mdash;As regards the geological age
+of this great volcanic series much uncertainty exists,
+owing to the absence of marine forms in the inter-trappean
+beds. One single species, <i>Cardita variabilis</i>,
+has been observed as occurring in these beds, and in
+the limestone below the base of the trap at Dudukur.
+The <i>facies</i> of the forms in this limestone is Tertiary;
+but there is a remarkable absence of characteristic
+genera. On the other hand, Mr. Blanford states that
+the bedded traps are seen to underlie the Eocene
+Tertiary strata with <i>Nummulites</i> in Guzerat and
+Cutch,<a name="FNanchor_2_156" id="FNanchor_2_156"></a><a href="#Footnote_2_156" class="fnanchor">[2]</a> which would appear to determine the limit of
+their age in one direction. On balancing the evidence,
+however, it is tolerably clear that the volcanic eruptions
+commenced towards the close of the Cretaceous
+period, and continued into the commencement of the
+Tertiary, thus bridging over the interval between the
+two epochs; and since the greater sheets have been
+exposed throughout the whole of the Tertiary and
+Quarternary periods, it is not surprising if they have
+suffered enormously from denuding agencies, and
+that any craters or cones of eruption that may once
+have existed have disappeared.</p>
+
+<div class="footnote"><p><a name="Footnote_1_155" id="Footnote_1_155"></a><a href="#FNanchor_1_155"><span class="label">[1]</span></a> The Deccan Traps have been described by Sykes, <i>Geol. Trans.</i>, 2nd
+Series, vol. iv.; also Rev. S. Hislop, "On the Geology of the Neighbourhood
+of Nagpur, Central India," <i>Quart. Journ. Geol. Soc.</i>, vol. x.
+p. 274; and <i>Ibid.</i>, vol. xvi. p. 154. Also, H. B. Medlicott and W.
+T. Blanford, <i>Manual of the Geology of India</i>, vol. i. (1879).</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_156" id="Footnote_2_156"></a><a href="#FNanchor_2_156"><span class="label">[2]</span></a> Blanford, <i>Geology of Abyssinia</i>, p. 185.</p></div>
+<p><span class="pagenum"><a name="Page_190" id="Page_190">[Pg 190]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_V_CHAPTER_II" id="PART_V_CHAPTER_II"></a>CHAPTER II.
+<br /><br />
+ABYSSINIAN TABLE-LANDS.</h2>
+
+
+<p>Another region in which the volcanic phenomena
+bear a remarkable analogy to those of Central India,
+just described, is that of Abyssinia. Nor are these
+tracts so widely separated that they may not be
+considered as portions of one great volcanic area
+extending from Abyssinia, through Southern Arabia,
+into Cutch and the Deccan, in the one direction,
+while the great volcanic cones of Kenia and Kilimanjaro,
+with their surrounding tracts of volcanic matter,
+may be the extreme prolongations in the other. Along
+this tract volcanic operations are still active in the
+Gulf of Aden; and cones quite unchanged in form,
+and evidently of very recent date, abound in many
+places along the coast both of Arabia and Africa.
+The volcanic formations of this tract are, however,
+much more recent than those which occupy the
+high plateaux of Central and Southern Abyssinia
+of which we are about to speak.</p>
+
+<p>(<i>a.</i>) <i>Physical Features.</i>&mdash;Abyssinia forms a compact
+region of lofty plateaux intersected by deep
+valleys, interposed between the basin of the Nile on
+the west, and the low-lying tract bordering the Red
+Sea and the Indian Ocean on the east. The plateaux
+are deeply intersected by valleys and ravines, giving
+<span class="pagenum"><a name="Page_191" id="Page_191">[Pg 191]</a></span>birth to streams which feed the head waters of the
+Blue Nile (Bahr el Arak) and the Atbara. Several
+fine lakes lie in the lap of the mountains, of which
+the Zana, or Dembia, is the largest, and next Ashangi,
+visited by the British army on its march to Magdala
+in 1868, and which, from its form and the volcanic
+nature of the surrounding hills, appears to occupy
+the hollow of an extinct crater. The table-land of
+Abyssinia reaches its highest elevation along the
+eastern and southern margin, where its average
+height may be 8,000 to 10,000 feet; but some peaks
+rise to a height of 12,000 to 15,000 feet in Shoa and
+Ankobar.<a name="FNanchor_1_157" id="FNanchor_1_157"></a><a href="#Footnote_1_157" class="fnanchor">[1]</a></p>
+
+<p>(<i>b.</i>) <i>Basaltic Lava Sheets.</i>&mdash;An enormous area of
+this country seems to be composed of volcanic rocks
+chiefly in the form of sheets of basaltic lava, which
+rise into high plateaux, and break off in steep&mdash;sometimes
+precipitous&mdash;mural escarpments along the
+sides of the valleys. These are divisible into the
+following series:&mdash;</p>
+
+<p>(1) <i>The Ashangi Volcanic Series.</i>&mdash;The earliest
+forerunners of the more recent lavas seem to have
+been erupted in Jurassic times, in the form of sheets
+of contemporaneous basalt or dolerite amongst the
+Antola limestones which are of this period. But the
+great mass of the volcanic rocks are much more
+recent, and may be confidently referred to the late
+Cretaceous or early Tertiary epochs. Their resemblance
+to the great trappean series of Western India,
+even in minute particulars, is referred to by Mr.
+Blanford, who suggests the view that they belong
+to one and the same great series of lava-flows extruded
+over the surface of this part of the globe.
+<span class="pagenum"><a name="Page_192" id="Page_192">[Pg 192]</a></span>This view is inherently probable. They consist of
+basalts and dolerites, generally amygdaloidal, with
+nodules of agate and zeolite, and are frequently coated
+with green-earth (chlorite). Beds of volcanic ash
+or breccia also frequently occur, and often contain
+augite crystals. At Senafé, hills of trachyte passing
+into claystone and basalt were observed by Mr.
+Blanford, but it is not clear what are their relations
+to the plateau-basaltic sheets.<a name="FNanchor_2_158" id="FNanchor_2_158"></a><a href="#Footnote_2_158" class="fnanchor">[2]</a></p>
+
+<p>(2) <i>Magdala Volcanic Series.</i>&mdash;This is a more recent
+group of volcanic lavas, chiefly distinguished from
+the lower, or Ashangi, group, by the occurrence of
+thick beds of trachyte, usually more or less crystalline,
+and containing beautiful crystals of sanidine.
+The beds of trachyte break off in precipitous scarps,
+and being of great thickness and perfectly horizontal,
+are unusually conspicuous. Mr. Blanford says, with
+regard to this group, that there is a remarkable resemblance
+in its physical aspect to the scenery of the
+Deccan and the higher valleys of the Western Ghats
+of India, but the peculiarities of the landscape are
+exaggerated in Abyssinia. Many of the trachytic
+beds are brecciated and highly columnar; sedimentary
+beds are also interstratified with those of volcanic
+origin. The Magdala group is unconformable to
+that of Ashangi in some places. A still more recent
+group of volcanic rocks appears to occur in the
+neighbourhood of Senafé, consisting of amorphous
+masses of trachyte, often so fine-grained and compact
+as to pass into claystone and to resemble sandstone.
+At Akub Teriki the rocks appear to be in the immediate
+vicinity of an ancient vent of eruption.</p>
+
+<p>From what has been said, it will be apparent that
+<span class="pagenum"><a name="Page_193" id="Page_193">[Pg 193]</a></span>Abyssinia offers volcanic phenomena of great interest
+for the observer. There is considerable variety in
+the rock masses, in their mode of distribution, and
+in the scenery which they produce. The extensive
+horizontal sheets of lava are suggestive of fissure-eruption
+rather than of eruption through volcanic
+craters; and although these may have once been in
+existence, denudation has left no vestiges of them at
+the present day. In all these respects the resemblance
+of the volcanic phenomena to those of Peninsular
+India is remarkably striking; it suggests the
+view that they are contemporaneous as regards the
+time of their eruption, and similar as regards their
+mode of formation.</p>
+
+<div class="footnote"><p><a name="Footnote_1_157" id="Footnote_1_157"></a><a href="#FNanchor_1_157"><span class="label">[1]</span></a> W. T. Blanford, <i>Geology of Abyssinia</i>, pp. 151-2.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_158" id="Footnote_2_158"></a><a href="#FNanchor_2_158"><span class="label">[2]</span></a> Blanford, <i>loc. cit.</i>, p. 182.</p></div>
+<p><span class="pagenum"><a name="Page_194" id="Page_194">[Pg 194]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_V_CHAPTER_III" id="PART_V_CHAPTER_III"></a>CHAPTER III.
+<br /><br />
+CAPE COLONY.</h2>
+
+
+<p><i>Basalt of the Plateau.</i>&mdash;The extensive sheets of
+plateau-basalt forming portions of the Neuweld range
+and the elevated table-land of Cape Colony, may be
+regarded as forerunners of those just described, and
+possibly contemporaneous with the Ashangi volcanic
+series of Abyssinia. The great basaltic sheets of
+the Cape Colony are found capping the highest
+elevations of the Camderboo and Stormberg ranges,
+as well as overspreading immense areas of less
+elevated land, to an extent, according to Professor
+A. H. Green, of at least 120,000 square miles.<a name="FNanchor_1_159" id="FNanchor_1_159"></a><a href="#Footnote_1_159" class="fnanchor">[1]</a>
+Amongst these sheets, innumerable dykes, and masses
+of solid lava which filled the old vents of eruption,
+are to be observed. The floor upon which the lava-floods
+have been poured out generally consists of the
+"Cave Sandstone," the uppermost of a series of
+deposits which had previously been laid down over
+the bed of an extensive lake which occupied this
+part of Africa during the Mesozoic period. After
+the deposition of this sandstone, the volcanic forces
+appear to have burst through the crust, and from
+<span class="pagenum"><a name="Page_195" id="Page_195">[Pg 195]</a></span>vents and fissures great floods of augitic lava, with
+beds of tuff, invaded the region occupied by the
+waters of the lake. The lava-sheets have since
+undergone extensive denudation, and are intersected
+by valleys and depressions eroded down through
+them into the sandstone floor beneath; and though
+the precise geological period at which they were
+extruded must remain in doubt, it appears probable
+that they may be referred to that of the Trias.<a name="FNanchor_2_160" id="FNanchor_2_160"></a><a href="#Footnote_2_160" class="fnanchor">[2]</a></p>
+
+<div class="footnote"><p><a name="Footnote_1_159" id="Footnote_1_159"></a><a href="#FNanchor_1_159"><span class="label">[1]</span></a> Green. "On the Geology of the Cape Colony," <i>Quart. Jour. Geol.
+Soc.</i>, vol. xliv. (1888).</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_160" id="Footnote_2_160"></a><a href="#FNanchor_2_160"><span class="label">[2]</span></a> The district lying along the south coast of Africa is described
+by Andrew G. Bain, in the <i>Trans. Geol. Soc.</i>, vol. vii. (1845); but
+there is little information regarding the volcanic region here referred to.</p></div>
+<p><span class="pagenum"><a name="Page_196" id="Page_196">[Pg 196]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_V_CHAPTER_IV" id="PART_V_CHAPTER_IV"></a>CHAPTER IV.
+<br /><br />
+VOLCANIC ROCKS OF PAST GEOLOGICAL PERIODS
+OF THE BRITISH ISLES.</h2>
+
+
+<p>It is beyond the scope of this work to describe the
+volcanic rocks of pre-Tertiary times over various parts
+of the globe. The subject is far too large to be treated
+otherwise than in a distinct and separate essay. I
+will therefore content myself with a brief enumeration
+of the formations of the British Isles in which contemporaneous
+volcanic action has been recognised.<a name="FNanchor_1_161" id="FNanchor_1_161"></a><a href="#Footnote_1_161" class="fnanchor">[1]</a></p>
+
+<p>There is little evidence of volcanic action throughout
+the long lapse of time extending backwards from
+the Cretaceous to the Triassic epochs, that is to say,
+throughout the Mesozoic or Secondary period, and it
+is not till we reach the Palæozoic strata that evidence
+of volcanic action unmistakably presents itself.</p>
+
+<p><i>Permian Period.</i>&mdash;In Ayrshire, and in the western
+parts of Devonshire, beds of felspathic porphyry, felstone
+and ash are interstratified with strata believed
+to be of Permian age. In Devonshire these have only
+recently been recognised by Dr. Irving and the author
+as of Permian age, the strata consisting of beds of
+breccia, lying at the base of the New Red Sandstone.
+Those of Ayrshire have long been recognised as of
+<span class="pagenum"><a name="Page_197" id="Page_197">[Pg 197]</a></span>the same period; as they rest unconformably on the
+coal measures, and consist of porphyrites, melaphyres,
+and tuffs of volcanic origin.</p>
+
+<p><i>Carboniferous Period.</i>&mdash;Volcanic rocks occur
+amongst the coal-measures of England and Scotland,
+while they are also found interbedded with the
+Carboniferous Limestone series in Derbyshire, Scotland,
+and Co. Limerick in Ireland. The rocks consist
+chiefly of basalt, dolerite, melaphyre and felstone.</p>
+
+<p><i>Devonian Period.</i>&mdash;Volcanic rocks of Devonian
+age occur in the South of Scotland, consisting of
+felstone-porphyries and melaphyres; also at Boyle,
+in Roscommon, and amongst the Glengariff beds
+near Killarney in Ireland.</p>
+
+<p><i>Upper Silurian Period.</i>&mdash;Volcanic rocks of this
+stage are only known in Ireland, on the borders of
+Cos. Mayo and Galway, west of Lough Mask, and at
+the extreme headland of the Dingle Promontory in
+Co. Kerry. They consist of porphyrites, felstones
+and tuffs, or breccias, contemporaneously erupted
+during the Wenlock and Ludlow stages. Around
+the flanks of Muilrea, beds of purple quartz-felstone
+with tuff are interstratified with the Upper Silurian
+grits and slates.</p>
+
+<p><i>Lower Silurian Period.</i>&mdash;Volcanic action was developed
+on a grand scale during the Arenig and Caradoc-Bala
+stages, both in Wales and the Lake district,
+and in the Llandeilo stage in the South of Scotland.
+The felspathic lavas, with their associated beds of
+tuff and breccia, rise into some of the grandest mountain
+crests of North Wales, such as those of Cader
+Idris, Aran Mowddwy, Arenig and Moel Wyn. A
+similar series is also represented in Ireland, ranging
+from Wicklow to Waterford, forming a double group
+<span class="pagenum"><a name="Page_198" id="Page_198">[Pg 198]</a></span>of felstones, porphyries, breccias, and ash-beds, with
+dykes of basalt and dolerite. The same series again
+appears amidst the Lower Silurian beds of Co. Louth,
+near Drogheda.</p>
+
+<p><i>Metamorphic Series presumably of Lower Silurian
+Age.</i>&mdash;If, as seems highly probable, the great metamorphic
+series of Donegal and Derry are the representatives
+in time of the Lower Silurian series,
+some of the great sheets of felspathic and hornblendic
+trap which they contain are referable to this
+epoch. These rocks have undergone a change in
+structure along with the sedimentary strata of which
+they were originally formed, so that the sheets of (presumably)
+augitic lava have been converted into hornblende-rock
+and schist. Similar masses occur in North
+Mayo, south of Belderg Harbour.</p>
+
+<p><i>Cambrian Period.</i>&mdash;In the Pass of Llanberis, along
+the banks of Llyn Padarn, masses of quartz-porphyry,
+felsite and agglomerate, or breccia, indicate volcanic
+action during this stage. These rocks underlie beds
+of conglomerate, slate and grit of the Lower Cambrian
+epoch, and, as Mr. Blake has shown, are clearly
+of volcanic origin, and pass upwards into the sedimentary
+strata of the period. A similar group, first
+recognised by Professor Sedgwick, stretches southwards
+from Bangor along the southern shore of the
+Menai Straits. Again, we find the volcanic eruptions
+of this epoch at St. David's, consisting of diabasic and
+felsitic lava, with beds of ash; and in the centre of
+England, amongst the grits and slates of Charnwood
+Forest presumably of Cambrian age, various felstones,
+porphyries, and volcanic breccias are found.</p>
+
+<p>Thus it will be seen that every epoch, from the
+earliest stage of the Cambrian to the Permian, in the
+<span class="pagenum"><a name="Page_199" id="Page_199">[Pg 199]</a></span>British Isles, gives evidence of the existence of volcanic
+action; from which we may infer that the
+originating cause, whatever it may be, has been in
+operation throughout all past geological time represented
+by living forms. The question of the condition
+of our globe in Archæan times, and earlier, is
+one which only can be discussed on theoretic ground,
+and is beyond the scope of this work.</p>
+
+<div class="footnote"><p><a name="Footnote_1_161" id="Footnote_1_161"></a><a href="#FNanchor_1_161"><span class="label">[1]</span></a> The reader is referred to Sir A. Geikie's Presidential Address to the
+Geological Society (1891) for the latest view of this subject.</p></div>
+
+<p><span class="pagenum"><a name="Page_200" id="Page_200">[Pg 200]</a></span></p>
+<hr class="major" />
+
+<div class="figcenter">
+<a name="MAP_2"></a>
+<a href="images/map2full.jpg">
+  <span class="center">VOLCANIC BAND OF THE MOLUCCAS.</span><br />
+  <img src="images/map2.jpg" alt="Map of Moluccas" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+Map showing the volcanic belt to which Krakatoa belongs. The shaded portion is volcanic.
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_201" id="Page_201">[Pg 201]</a></span></p>
+<hr class="major" />
+
+
+<h1><a name="PART_VI" id="PART_VI"></a>PART VI.
+<br /><br />
+SPECIAL VOLCANIC AND SEISMIC
+PHENOMENA.</h1>
+
+
+
+<hr class="major" />
+<h2><a name="PART_VI_CHAPTER_I" id="PART_VI_CHAPTER_I"></a>CHAPTER I.
+<br /><br />
+THE ERUPTION OF KRAKATOA IN 1883.</h2>
+
+
+<p>I propose to introduce here some account of one
+of the most terrible outbursts of volcanic action
+that have taken place in modern times; namely,
+the eruption of the volcano of Krakatoa (a corruption
+of Rakata) in the strait of Sunda, between
+the islands of Sumatra and Java, in the year 1883.
+The Malay Archipelago, of which this island once
+formed a member, is a region where volcanic action
+is constant, and where the outbursts are exceptionally
+violent. With the great island of Borneo
+as a solid, non-volcanic central core, a line of volcanic
+islands extends from Chedooba off the coast
+of Pegu through Sumatra, Java, Sumbawa, Flores,
+and, reaching the Moluccas, stretches northwards
+through the Philippines into Japan and Kamtschatka.
+This is probably the most active volcanic belt in the
+world, and the recent terrible earthquake and eruption
+in Japan (November, 1891) gives proof that the
+volcanic forces are as powerful and destructive as ever.<a name="FNanchor_1_162" id="FNanchor_1_162"></a><a href="#Footnote_1_162" class="fnanchor">[1]</a></p>
+
+<p><span class="pagenum"><a name="Page_202" id="Page_202">[Pg 202]</a></span></p><p>(<i>a.</i>) <i>Dormant Condition down to 1680.</i>&mdash;Down to
+the year 1680, this island, although from its form and
+structure evidently volcanic, appears to have been
+in a dormant state; its sides were covered with
+luxuriant forests, and numerous habitations dotted
+its shore. But in May of that year an eruption
+occurred, owing to which the aspect of Krakatoa
+as described by Vogel was entirely changed; the
+surface of the island when this writer passed on
+his voyage to Sumatra appeared burnt up and arid,
+while blocks of incandescent rock were being hurled
+into the air from four distinct points. After this first
+recorded eruption the island relapsed into a state of
+repose, and except for a stream of molten lava which
+issued from the northern extremity, there was no
+evidence of its dangerous condition. The luxuriant
+vegetation of the tropics speedily re-established
+itself, and the volcano was generally regarded as
+"extinct."<a name="FNanchor_2_163" id="FNanchor_2_163"></a><a href="#Footnote_2_163" class="fnanchor">[2]</a> History repeats itself; and the history
+of Vesuvius was repeated in the case of Krakatoa.</p>
+
+<p><span class="pagenum"><a name="Page_203" id="Page_203">[Pg 203]</a></span></p>
+
+<div class="figcenter">
+<a name="FIGURE_35">
+  <img src="images/figure35.jpg" alt="Map of Krakatoa" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 35.</span>&mdash;Map
+Of The Krakatoa Group Of Islands Before
+The Eruption Of August 1883 (From Admiralty Chart)
+</td></tr>
+</table>
+</div>
+
+<p>(<i>b.</i>) <i>Eruption of May, 1883.</i><a name="FNanchor_3_164" id="FNanchor_3_164"></a><a href="#Footnote_3_164" class="fnanchor">[3]</a>&mdash;On the morning of
+May 20, 1883, the inhabitants of Batavia, of Buitenzorg,
+and neighbouring localities, were surprised by a
+confused noise, mingled with detonations resembling
+the firing of artillery. The phenomena commenced
+between ten and eleven o'clock in the morning, and
+soon acquired such intensity as to cause general
+alarm. The detonations were accompanied by
+tremblings of the ground, of buildings and various
+objects contained in dwellings; but it was generally
+admitted that these did not proceed from earthquake
+shocks, but from atmospheric vibrations. No deviation
+of the magnetic needle was observed at the Meteorological
+Institute of Batavia; but a vertical oscillation
+was apparent, and persons who listened with the ear
+placed on the ground, even during the most violent
+detonations, could hear no subterranean noise whatever.
+It became clear that the sounds came from
+some volcano burst into activity; but it is strange that
+for two whole days it remained uncertain what was
+the particular volcano to which the phenomena were
+to be referred. The detonations appeared, indeed, to
+come from the direction of Krakatoa; but from
+<span class="pagenum"><a name="Page_204" id="Page_204">[Pg 204]</a></span>Serang, Anjer, and Merak, localities situated much
+nearer Krakatoa than Batavia, the telegraph announced
+that neither detonations nor atmospheric
+vibrations had been perceived. The distance between
+Batavia and Krakatoa is ninety-three English miles.
+The doubts thus experienced were, however, soon put
+to rest by the arrival of an American vessel under the
+command of A. R. Thomas, and of other ships which
+hailed from the straits of Sunda. From their accounts
+it was ascertained that in the direction of Krakatoa
+the heavens were clouded with ashes, and that a grand
+column of smoke, illumined from time to time by
+flashes of flame, arose from above the island. Thus
+after a repose of more than two hundred years, "the
+peaceable isle of Krakatoa, inhabited, and covered by
+thick forests, was suddenly awakened from its condition
+of fancied security."</p>
+
+<div class="figcenter">
+<a name="FIGURE_36">
+  <img src="images/figure36.jpg" alt="Section through Krakatoa" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 36.</span>&mdash;Section from Verlaten Island through Krakatoa, to show
+the outline before and after the eruption of August, 1888. The continuous
+line shows the former; the dotted line and shading, the latter;
+from which it will be observed that the original island has to a large
+extent disappeared. The line of section is shown in <a href="#FIGURE_35">Fig. 35</a>.
+</td></tr>
+</table>
+</div>
+
+<p>(<i>c.</i>) <i>Form and Appearance of the Island before the
+Eruption of 1883.</i>&mdash;From surveys made in 1849 and
+1881, it would appear that the island of Krakatoa
+consisted of three mountains or groups of mountains
+(Figs. <a href="#FIGURE_35">35</a>, <a href="#FIGURE_36">36</a>); the southern formed by the cone of Rakata
+(properly so called), rising with a scarped face
+above the sea to a height of over 800 mètres (2,622
+feet). Adjoining this cone, and rising from the centre of
+<span class="pagenum"><a name="Page_205" id="Page_205">[Pg 205]</a></span>the island, came the group of Danan, composed of
+many summits, probably forming part of the <i>enceinte
+annulaire</i> of a crater. And near the northern
+extremity of the isle, a third group of mammelated
+heights could be recognised under the general name
+of Perboewatan, from which issued several obsidian
+lava-flows, with a steep slope; these dated back perhaps
+to the period of the first known eruption of 1680.
+This large and mountainous island as it existed at the
+beginning of May, 1883, has been entirely destroyed
+by the terrible eruptions of that year, with the exception
+of the peripheric rim (composed of the most
+ancient of the volcanic rocks, andesite), of which Verlaten
+Island and Rakata formed a part, and one very
+small islet, which is noted on the maps as "rots"
+(rock), and on the new map of the Straits of Sunda
+of the Dutch Navy as that of "Bootsmansrots."<a name="FNanchor_4_165" id="FNanchor_4_165"></a><a href="#Footnote_4_165" class="fnanchor">[4]</a></p>
+
+<p>As shown by the map in the Report of the Royal
+Society, the group of islands which existed previous
+to 1883 were but the unsubmerged portions of one
+vast volcanic crater, built up of a remarkable variety
+of lava allied to the andesite of the Java volcanoes,
+but having a larger percentage of silica, and hence
+falling under the head of "enstatite-dacite."<a name="FNanchor_5_166" id="FNanchor_5_166"></a><a href="#Footnote_5_166" class="fnanchor">[5]</a> That
+these volcanic rocks are of very recent origin is shown
+by the fact, ascertained by Verbeek, that beneath them
+occur deposits of Post-Tertiary age, and that these in
+turn rest on the Tertiary strata which are widely distributed
+through Sumatra, Java, and the adjoining
+islands. According to the reasoning of Professor
+Judd, the Krakatoa group at an early period of its
+history presented the form of a magnificent crater-cone,
+several miles in circumference at the base, which
+<span class="pagenum"><a name="Page_206" id="Page_206">[Pg 206]</a></span>subsequent eruptions shattered into fragments or blew
+into the air in the form of dust, ashes, and blocks
+of lava, while the central part collapsed and fell in,
+leaving a vast circular ring like the ancient crater of
+Somma (see <a href="#FIGURE_6">Fig. 6, p. 43</a>), and he supposes the
+former eruptions to have been on a scale exceeding
+in magnificence those which have caused such
+world-wide interest within the last few years.</p>
+
+<p>(<i>d.</i>) <i>Eruption of 26th to 28th of August.</i>&mdash;It was,
+as we have seen, in the month of May that, in the
+language of Chev. Verbeek, "the volcano of Krakatoa
+chose to announce in a high voice to the inhabitants
+of the Archipelago that, although almost nothing
+amongst the many colossal volcanic mountains of the
+Indies, it yielded to none of them in regard to its power."
+These eruptions were, however, only premonitory of
+the tremendous and terrible explosion which was to
+commence on Sunday, the 26th of August, and which
+continued for several days subsequently. A little
+after noon of that day, a rumbling noise accompanied
+by short and feeble explosions was heard at Buitenzorg,
+coming from the direction of Krakatoa; and
+similar sounds were heard at Anjer and Batavia a
+little later. Soon these detonations augmented in
+intensity, especially about five o'clock in the evening;
+and news was afterwards received that the sounds
+had been heard in the isle of Java. These sounds
+increased still more during the night, so that few
+persons living on the west side of the isle of Java
+were able to sleep. At seven in the morning there
+came a crash so formidable, that those who had hoped
+for a little sleep at Buitenzorg leaped from their beds.
+Meanwhile the sky, which had up to this time been
+clear, became overcast, so that by ten o'clock it
+<span class="pagenum"><a name="Page_207" id="Page_207">[Pg 207]</a></span>became necessary to have recourse to lamps, and the
+air became charged with vapour. Occasional shocks
+of earthquake were now felt. Darkness became
+general all over the straits and the bordering coasts.
+Showers of ashes began to fall. The repeated shocks
+of earthquake, and the rapid discharges of subterranean
+artillery, all combined to show that an eruption
+of even greater violence than that of May was in
+progress at the isle of Krakatoa.</p>
+
+<p>But the most interested witnesses to this terrible
+outburst were those on board the ships plying through
+the straits. Amongst these was the <i>Charles Bal</i>, a
+British vessel under the command of Captain Watson.
+This ship was ten miles south of the volcano on Sunday
+afternoon, and therefore well in sight of the island
+at the time when the volcano had entered upon its
+paroxysmal state of action. Captain Watson describes
+the island as being covered by a dense black cloud,
+while sounds like the discharges of artillery occurred
+at intervals of a second of time; and a crackling noise
+(probably arising from the impact of fragments of
+rock ascending and descending in the atmosphere)
+was heard by those on board. These appearances
+became so threatening towards five o'clock in the
+evening, that the commander feared to continue his
+voyage and began to shorten sail. From five to six
+o'clock a rain of pumice in large pieces, quite warm,
+fell upon the ship, which was one of those that escaped
+destruction during this terrible night.<a name="FNanchor_6_167" id="FNanchor_6_167"></a><a href="#Footnote_6_167" class="fnanchor">[6]</a></p>
+
+<p>(<i>e.</i>) <i>Electrical Phenomena.</i>&mdash;During this eruption,
+electrical phenomena of great splendour were observed.
+<span class="pagenum"><a name="Page_208" id="Page_208">[Pg 208]</a></span>Captain Wooldbridge, viewing the eruption
+in the afternoon of the 26th from a distance of forty
+miles, speaks of a great vapour-cloud looking like an
+immense wall being momentarily lighted up "by
+bursts of forked lightning like large serpents rushing
+through the air. After sunset this dark wall resembled
+a blood-red curtain, with edges of all shades of
+yellow, the whole of a murky tinge, through which
+gleamed fierce flashes of lightning." As Professor
+Judd observes, the abundant generation of atmospheric
+electricity is a familiar phenomenon in all
+volcanic eruptions on a grand scale. The steam-jets
+rushing through the orifices of the earth's crust
+constitute an enormous hydro-electrical engine, and
+the friction of the ejected materials striking against
+one another in their ascent and descent also does
+much in the way of generating electricity.<a name="FNanchor_7_168" id="FNanchor_7_168"></a><a href="#Footnote_7_168" class="fnanchor">[7]</a> It has
+been estimated by several observers that the column of
+watery vapour ascended to a height of from twelve to
+seventeen and even twenty-three miles; and on reaching
+the upper strata of the atmosphere, it spread itself
+out in a vast canopy resembling "the pine-tree" form
+of Vesuvian eruptions; and throughout the long night
+of the 27th this canopy continued to extend laterally,
+and the particles of dust which it enclosed began to
+descend slowly through the air.</p>
+
+<p>(<i>f.</i>) <i>Formation of Waves.</i>&mdash;This tremendous outburst
+of volcanic forces, which to a greater or less
+extent influenced the entire surface of the globe, gave
+rise to waves which traversed both air and ocean; and
+in consequence of the large number of observatories
+scattered all over the globe, and the excellence and
+delicacy of the instruments of observation, we are
+<span class="pagenum"><a name="Page_209" id="Page_209">[Pg 209]</a></span>put in possession of the remarkable results which
+have been obtained from the collection of the observations
+in the hands of competent specialists.
+The results are related <i>in extenso</i> in the Report
+of the Royal Society, illustrated by maps and diagrams,
+and are worthy of careful study by those
+interested in terrestrial phenomena. A brief summary
+is all that can be given here, but it will probably
+suffice to bring home to the reader the magnitude
+and grandeur of the eruption.</p>
+
+<p>The vibrations or waves generated in August, 1883,
+at Krakatoa may be arranged under three heads:
+(1) Atmospheric Waves; (2) Sound Waves; and (3)
+Oceanic Waves; which I will touch upon in the order
+here stated.</p>
+
+<p>(1) <i>Atmospheric Waves.</i>&mdash;These phenomena have
+been ably handled by General Strachey,<a name="FNanchor_8_169" id="FNanchor_8_169"></a><a href="#Footnote_8_169" class="fnanchor">[8]</a> from a
+large number of observations extending all over the
+globe. From these it has been clearly established that
+an atmospheric wave, originating at Krakatoa as a
+centre, expanded outwards in a circular form and
+travelled onwards till it became a great circle at a
+distance of 180 degrees from its point of origin, after
+which it still advanced, but now gradually contracting
+to a node at the antipodes of Krakatoa; that is to
+say, at a point over the surface of North America,
+situated in lat. 6° N. and long. 72° W. (or thereabout).
+Having attained this position, the wave was reflected
+or reproduced, expanding outwards for 180 degrees
+and travelling backwards again to Krakatoa, from
+which it again started, and returning to its original
+form again overspread the globe. This wonderful
+repetition, due to the spherical form of the earth, was
+<span class="pagenum"><a name="Page_210" id="Page_210">[Pg 210]</a></span>observed no fewer than seven times, though with such
+diminished force as ultimately to be outside the range
+of observation by the most sensitive instruments. It
+is one of the triumphs of modern scientific appliances
+that the course of such a wave, generated in a fluid
+surrounding a globe, which might be demonstrated on
+mathematical principles, has been actually determined
+by experiments carried on over so great an area.</p>
+
+<p>(2) <i>Sound Waves.</i>&mdash;If the sound-waves produced
+at the time of maximum eruption were not quite as
+far-reaching as those of the air, they were certainly
+sufficiently surprising to be almost incredible, were it
+not that they rest, both as regards time and character,
+upon incontestible authority. The sound of the
+eruption, resembling that of the discharge of artillery,
+was heard not only over nearly all parts of Sumatra,
+Java, and the coast of Borneo opposite the Straits of
+Sunda, but at places over two thousand miles distant
+from the scene of the explosions. Detailed accounts,
+collected with great care, are given in the Report of
+the Royal Society, from which the following are
+selected as examples:&mdash;</p>
+
+<blockquote><p>1. At the port of Acheen, at the northern extremity of Sumatra,
+distant 1,073 miles, it was supposed that the port was being
+attacked, and the troops were put under arms.</p>
+
+<p>2. At Singapore, distant 522 miles, two steamers were dispatched
+to look out for the vessel which was supposed to be
+firing guns as signals of distress.</p>
+
+<p>3. At Bankok, in Siam, distant 1,413 miles, the report was
+heard on the 27th; as also at Labuan, in Borneo, distant 1,037
+miles.</p>
+
+<p>4. At places in the Philippine Islands, distant about 1,450
+miles, detonations were heard on the 27th, at the time of the
+eruption.</p></blockquote>
+
+<p>The above places lie northwards of Krakatoa. In
+<span class="pagenum"><a name="Page_211" id="Page_211">[Pg 211]</a></span>the opposite direction, we have the following examples:&mdash;</p>
+
+<blockquote><p>5. At Perth, in Western Australia, distant 1,092 miles, sounds
+as of guns firing at sea were heard; and at the Victorian Plains,
+distant about 1,700 miles, similar sounds were heard.</p>
+
+<p>6. In South Australia, at Alice's Springs, Undoolga, and
+other places at distances of over 2,000 miles, the sounds of the
+eruption were also heard.</p>
+
+<p>7. In a westerly direction at Dutch Bay, Ceylon, distant
+2,058 miles, the sounds were heard between 7 a.m. and 10 a.m.
+on the morning of the 27th of August.</p>
+
+<p>8. Lastly, at the Chagos Islands, distant 2,267 miles, the detonations
+were audible between 10 and 11 a.m. of the same day.</p></blockquote>
+
+<p>Some of the above distances are so great that we
+may fail to realise them; but they will be more easily
+appreciated, perhaps, if we change the localities to our
+own side of the globe, and take two or three cases
+with similar distances. Then, if the eruption had taken
+place amongst the volcanoes of the Canaries, the detonations
+would have been heard at Gibraltar, at Lisbon,
+at Portsmouth, Southampton, Cork, and probably at
+Dublin and Liverpool; or, again, supposing the eruption
+had taken place on the coast of Iceland, the
+report would have been heard all over the western
+and northern coasts of the British Isles, as well as at
+Amsterdam and the Hague. The enormous distance
+to which the sound travelled in the case of Krakatoa
+was greatly due to the fact that the explosions took
+place at the surface of the sea, and the sound was
+carried along that surface uninterruptedly to the
+localities recorded; a range of mountains intervening
+would have cut off the sound-wave at a comparatively
+short distance from its source.</p>
+
+<p>(3) <i>Oceanic Waves.</i>&mdash;As may be supposed, the
+<span class="pagenum"><a name="Page_212" id="Page_212">[Pg 212]</a></span>eruption gave rise to great agitation of the ocean
+waters with various degrees of vertical oscillation;
+but according to the conclusions of Captain Wharton,
+founded on numerous data, the greatest wave seems
+to have originated at Krakatoa about 10 a.m. on the
+27th of August, rising on the coasts of the Straits of
+Sunda to a height of fifty feet above the ordinary sea-level.
+This wave appears to have been observed over
+at least half the globe. It travelled westwards to the
+coast of Hindostan and Southern Arabia, ultimately
+reaching the coasts of France and England. Eastwards
+it struck the coast of Australia, New Zealand,
+the Sandwich Islands, Alaska, and the western coast
+of North America; so that it was only the continent
+of North and South America which formed a barrier
+(and that not absolute) to the circulation of this
+oceanic wave all over the globe. The destruction to
+life and property caused by this wave along the coasts
+of Sunda was very great. Combined with the earthquake
+shocks (which, however, were not very severe),
+the tremendous storm of wind, the fall of ashes
+and cinders, and the changes in the sea-bed, it produced
+in the Straits of Sunda for some time after the
+eruption a disastrous transformation. Lighthouses
+had been swept away; all the old familiar landmarks
+on the shore were obscured by a vast deposit of
+volcanic dust; the sea itself was encumbered with
+enormous quantities of floating pumice, in many
+places of such thickness that no vessel could force its
+way through them; and for months after the eruption
+one of the principal channels was greatly obstructed
+by two islands which had arisen in its midst. The
+Sebesi channel was completely blocked by banks
+composed of volcanic materials, and two portions of
+<span class="pagenum"><a name="Page_213" id="Page_213">[Pg 213]</a></span>these banks rose above the sea as islands, which
+received the name of "Steers Island" and "Calmeyer
+Island"; but these, by the action of the waves, have
+since been completely swept away, and the materials
+strewn over the bed of the sea.<a name="FNanchor_9_170" id="FNanchor_9_170"></a><a href="#Footnote_9_170" class="fnanchor">[9]</a></p>
+
+<p>(<i>g.</i>) <i>Atmospheric Effects.</i>&mdash;But the face of nature,
+even in her most terrific and repulsive aspect, is seldom
+altogether unrelieved by some traces of beauty.
+In contrast to the fearful and disastrous phenomena
+just described, is to be placed the splendour of the
+heavens, witnessed all over the central regions of
+the globe throughout a period of several months after
+the eruption of 1883, which has been ably treated
+by the Hon. Rollo Russell and Mr. C. D. Archibald,
+in the Royal Society's Report.</p>
+
+<p>When the particles of lava and ashes mingled with
+vapour were projected into the air with a velocity
+greater than that of a ball discharged from the largest
+Armstrong gun, these materials were carried by the
+prevalent trade-winds in a westerly direction, and
+some of them fell on the deck of ships sailing in
+the Indian Ocean as far as long. 80° E., as in the case
+of the <i>British Empire</i>&mdash;on which the particles fell on
+the 29th of August, at a distance of 1,600 miles from
+Krakatoa. But far beyond this limit, the finer particles
+of dust (or rather minute crystals of felspar and other
+minerals), mingled with vapour of water, were carried
+by the higher currents of the air as far as the Seychelles
+and Africa,&mdash;not only the East coast, but also
+the West, as Cape Coast Castle on the Gold Coast; to
+Paramaribo, Trinidad, Panama, the Sandwich Isles,
+<span class="pagenum"><a name="Page_214" id="Page_214">[Pg 214]</a></span>Ceylon and British India, at all of which places during
+the month of September the sun assumed tints of blue
+or green, as did also the moon just before and after the
+appearance of the stars;<a name="FNanchor_10_171" id="FNanchor_10_171"></a><a href="#Footnote_10_171" class="fnanchor">[10]</a> and from the latter end of
+September and for several months, the sky was remarkable
+for its magnificent coloration; passing from
+crimson through purple to yellow, and melting away
+in azure tints which were visible in Europe and the
+British Isles; while a large corona was observed round
+both the sun and moon. These beautiful sky effects
+were objects of general observation throughout the
+latter part of the year 1883 and commencement of the
+following year.</p>
+
+<p>The explanation of these phenomena may be briefly
+stated. The fine particles, consisting for the most
+part of translucent crystals, or fragments of crystals,
+formed a canopy high up in the atmosphere, being
+gradually spread over both sides of the equator till it
+formed a broad belt, through which the rays of the
+sun and moon were refracted. Towards dawn and
+sunset they were refracted and reflected from the
+facets of the crystal, and thus underwent decomposition
+into the prismatic colours; as do the rays of the
+sun when refracted and reflected from the particles of
+moisture in a rain-cloud. The subject is one which
+cannot be fully dealt with here, and is rather outside
+the scope of this work.</p>
+
+<p>(<i>h.</i>) <i>Origin of the Eruption.</i>&mdash;The ultimate cause of
+volcanic eruptions is treated in a subsequent chapter,
+nor is that of Krakatoa essentially different from
+others. It was remarkable, however, both for the
+magnitude of the forces evoked and the stupendous
+<span class="pagenum"><a name="Page_215" id="Page_215">[Pg 215]</a></span>scale of the resulting phenomena. It is evident that
+water played an important part in these phenomena,
+though not as the prime mover;&mdash;any more than water
+in the boiler of a locomotive is the prime mover in
+the generation of the steam. Without the fuel in the
+furnace the steam would not be produced; and the
+amount of steam generated will be proportional to
+the quantity and heat of the fuel in the furnace and
+the quantity of water in the boiler. In the case of
+Krakatoa, both these elements were enormous and
+inexhaustible. The volcanic chimney (or system of
+chimneys), being situated on an island, was readily
+accessible to the waters of the ocean when fissures
+gave them access to the interior molten matter. That
+such fissures were opened we may well believe. The
+earthquakes which occurred at the beginning of May,
+and later on, on the 27th of that month, may indicate
+movements of the crust by which water gained access.
+It appears that in May the only crater in a state of
+activity was that of Perboewatan; in June another
+crater came into action, connected with Danan in the
+centre of the island, and in August a third burst forth.
+Thus there was progressive activity up to the commencement
+of the grand eruption of the 26th of that
+month.<a name="FNanchor_11_172" id="FNanchor_11_172"></a><a href="#Footnote_11_172" class="fnanchor">[11]</a> During this last paroxysmal stage, the centre
+of the island gave way and sunk down, when the waters
+of the ocean gained free access, and meeting with the
+columns of molten matter rising from below originated
+the prodigious masses of steam which rose into the
+air.</p>
+
+<p>(<i>i.</i>) <i>Cause of the Detonations.</i>&mdash;The detonations
+which accompanied the last great eruption are
+repeatedly referred to in all the accounts. These
+<span class="pagenum"><a name="Page_216" id="Page_216">[Pg 216]</a></span>may have been due, not only to the sudden explosions
+of steam directly produced by the ocean water coming
+in contact with the molten lava, but by dissociation of
+the vapour of water at the critical point of temperature
+into its elements of oxygen and hydrogen; the
+reunion of these elements at the required temperature
+would also result in explosions.</p>
+
+<p>The phenomena attending this great volcanic eruption,
+so carefully tabulated and critically examined,
+will henceforth be referred to as constituting an epoch
+in the history of volcanic action over the globe, and be
+of immense value for reference and comparison.</p>
+
+<div class="footnote"><p><a name="Footnote_1_162" id="Footnote_1_162"></a><a href="#FNanchor_1_162"><span class="label">[1]</span></a> The eruption of Krakatoa has been the subject of an elaborate
+Report published by the Royal Society, and is also described in a
+work by Chevalier R. D. M. Verbeek, Ingenieur en Chef des Mines,
+and published by order of the Governor-General of the Netherland
+Indies (1886). See also an Article by Sir R. S. Ball in the <i>Contemporary
+Review</i> for November, 1888.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_163" id="Footnote_2_163"></a><a href="#FNanchor_2_163"><span class="label">[2]</span></a> Verbeek, <i>loc. cit.</i>, p. 4.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_164" id="Footnote_3_164"></a><a href="#FNanchor_3_164"><span class="label">[3]</span></a> The account of this eruption is a free translation from Verbeek.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_165" id="Footnote_4_165"></a><a href="#FNanchor_4_165"><span class="label">[4]</span></a> Verbeek, <i>loc. cit.</i>, p. 160.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_166" id="Footnote_5_166"></a><a href="#FNanchor_5_166"><span class="label">[5]</span></a> Judd, <i>Rep. R. S.</i></p></div>
+
+<div class="footnote"><p><a name="Footnote_6_167" id="Footnote_6_167"></a><a href="#FNanchor_6_167"><span class="label">[6]</span></a> A fuller account by Prof. Judd will be found in the <i>Report of the
+Royal Society</i>, p. 14. Several vessels at anchor were driven ashore on
+the straits owing to the strong wind which arose.</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_168" id="Footnote_7_168"></a><a href="#FNanchor_7_168"><span class="label">[7]</span></a> Judd, <i>Report</i>, p. 21.</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_169" id="Footnote_8_169"></a><a href="#FNanchor_8_169"><span class="label">[8]</span></a> <i>Report</i>, Part ii.</p></div>
+
+<div class="footnote"><p><a name="Footnote_9_170" id="Footnote_9_170"></a><a href="#FNanchor_9_170"><span class="label">[9]</span></a> In this eruption, 36,380 human beings perished, of whom 37 were
+Europeans; 163 villages (<i>kampoengs</i>) were entirely, and 132 partially,
+destroyed.&mdash;Verbeek, <i>loc. cit.</i>, p. 79.</p></div>
+
+<div class="footnote"><p><a name="Footnote_10_171" id="Footnote_10_171"></a><a href="#FNanchor_10_171"><span class="label">[10]</span></a> Verbeek, <i>loc. cit.</i>, p. 144-5. The dust put a girdle round the earth
+in thirteen days.</p></div>
+
+<div class="footnote"><p><a name="Footnote_11_172" id="Footnote_11_172"></a><a href="#FNanchor_11_172"><span class="label">[11]</span></a> Verbeek, <i>loc. cit.</i>, p. 30.</p></div>
+<p><span class="pagenum"><a name="Page_217" id="Page_217">[Pg 217]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_VI_CHAPTER_II" id="PART_VI_CHAPTER_II"></a>CHAPTER II.
+<br /><br />
+EARTHQUAKES.</h2>
+
+
+<p><i>Connection of Earthquakes with Volcanic Action.</i>&mdash;The
+connection between earthquake shocks and
+volcanic eruptions is now so generally recognised
+that it is unnecessary to insist upon it here. All
+volcanic districts over the globe are specially liable
+to vibrations of the crust; but at the same time it is
+to be recollected that these movements visit countries
+occasionally from which volcanoes, either recent or
+extinct, are absent; in which cases we may consider
+earthquake shocks to be abortive attempts to originate
+volcanic action.</p>
+
+<p>(<i>a.</i>) <i>Origin.</i>&mdash;From the numerous observations
+which have been made regarding the nature of these
+phenomena by Hopkins, Lyell, and others, it seems
+clearly established that earthquakes have their origin
+in some sudden impact of gas, steam, or molten matter
+impelled by gas or steam under high pressure, beneath
+the solid crust.<a name="FNanchor_1_173" id="FNanchor_1_173"></a><a href="#Footnote_1_173" class="fnanchor">[1]</a> How such impact originates we need
+<span class="pagenum"><a name="Page_218" id="Page_218">[Pg 218]</a></span>not stop to inquire, as the cause is closely connected
+with that which produces volcanic eruptions. The
+effect, however, of such impact is to originate a wave
+of translation through the crust, travelling outwards
+from the point, or focus, on the surface immediately
+over the point of impact.<a name="FNanchor_2_174" id="FNanchor_2_174"></a><a href="#Footnote_2_174" class="fnanchor">[2]</a> These waves of translation
+can in some cases be laid down on a map, and
+are called "isoseismal curves," each curve representing
+approximately an equal degree of seismal intensity;
+as shown on the chart of a part of North America
+affected by the great Charleston earthquake. (<a href="#FIGURE_37">Fig. 37</a>.)
+Mr. Hopkins has shown that the earthquake-wave,
+when it passes through rocks differing in density and
+elasticity, changes in some degree not only its velocity,
+but its direction; being both refracted and reflected
+in a manner analogous to that of light when it passes
+from one medium to another of different density.<a name="FNanchor_3_175" id="FNanchor_3_175"></a><a href="#Footnote_3_175" class="fnanchor">[3]</a>
+When a shock traverses the crust through a thickness
+of several miles it will meet with various kinds of rock
+as well as with fissures and plications of the strata,
+owing to which its course will be more or less modified.</p>
+
+<p>(<i>b.</i>) <i>Formation of Fissures.</i>&mdash;During earthquake
+movements, fissures may be formed in the crust, and
+filled with gaseous or melted matter which may not
+in all cases reach the surface; and, on the principle
+that volcanoes are safety-valves for regions beyond
+their immediate influence, we may infer that the earthquake
+shock, which generally precedes the outburst of
+<span class="pagenum"><a name="Page_219" id="Page_219">[Pg 219]</a></span>a volcano long dormant, finds relief by the eruption
+which follows; so that whatever may be the extent of
+the disastrous results of such an eruption, they would
+be still more disastrous if there had been no such
+safety-valve as that afforded by a volcanic vent. Thus,
+probably, owing to the extinction of volcanic activity
+in Syria, the earthquakes in that region have been
+peculiarly destructive. For example, on January 1,
+1837, the town of Safed west of the Jordan valley was
+completely destroyed by an earthquake in which most
+of the inhabitants perished. The great earthquakes
+of Aleppo in the present century, and of Syria in the
+middle of the eighteenth, were of exceptional severity.
+In that of Syria, which took place in 1759, and which
+was protracted during a period of three months, an
+area of 10,000 square leagues was affected. Accon,
+Saphat, Baalbeck, Damascus, Sidon, Tripoli, and other
+places were almost entirely levelled to the ground;
+many thousands of human beings lost their lives.<a name="FNanchor_4_176" id="FNanchor_4_176"></a><a href="#Footnote_4_176" class="fnanchor">[4]</a>
+Other examples might be cited.</p>
+
+<p>(<i>c.</i>) <i>Earthquake Waves.</i>&mdash;We have now to return to
+the phenomena connected with the transmission of
+earthquake-waves. The velocity of transmission
+through the earth is very great, and several attempts
+have been made to measure this velocity with accuracy.
+The most valuable of such attempts are those connected
+with the Charleston and Riviera shocks. Fortunately,
+owing to the perfection of modern appliances, and the
+number of observers all over the globe, these results
+are entitled to great confidence. The phenomena
+connected with the Charleston earthquake, which took
+<span class="pagenum"><a name="Page_220" id="Page_220">[Pg 220]</a></span>place on the 31st of August, 1886, are described in
+great detail by Captain Clarence E. Dutton, of the
+U.S. Ordnance Corps.<a name="FNanchor_5_177" id="FNanchor_5_177"></a><a href="#Footnote_5_177" class="fnanchor">[5]</a> The conclusions arrived at
+are;&mdash;that as regards the depth of the focal point, this is
+estimated at twelve miles, with a probable error of less
+than two miles; while, as regards the rate of travel of
+the earthquake-wave, the estimate is (in one case)
+about 3.236 miles per second; and in another about
+3.226 miles per second.</p>
+
+<p>On the other hand, in the case of the earthquake of
+the Riviera, which took place on the 23rd of February,
+1887, at 5.30 a.m. (local time), the vibrations of which
+appear to have extended across the Atlantic, and to
+have sensibly affected the seismograph in the Government
+Signal Office at Washington, the rate of travel
+was calculated at about 500 miles per hour, less than
+one-half that determined in the case of Charleston;
+but Captain Dutton claims, and probably with justice,
+that the results obtained in the latter case are far
+more reliable than any hitherto arrived at.</p>
+
+<p>(<i>d.</i>) <i>Oceanic Waves.</i>&mdash;When the originating impact
+takes place under the bed of the ocean&mdash;either by a
+sudden up-thrust of the crust to the extent, let us
+suppose, of two or three feet, or by an explosion from
+a submarine volcano&mdash;a double wave is formed, one
+travelling through the crust, the other through the
+ocean; and as the rate of velocity of the former is
+greatly in excess of that of the latter, the results on
+their reaching the land are often disastrous in the
+extreme. It is the ocean-wave, however, which is the
+more important, and calls for special consideration. If
+the impact takes place in very deep water, the whole
+mass of the water is raised in the form of a low dome,
+<span class="pagenum"><a name="Page_221" id="Page_221">[Pg 221]</a></span>sloping equally away in all directions; and it commences
+to travel outwards as a wave with an advancing
+crest until it approaches the coast and enters
+shallow water. The wave then increases in height,
+and the water in front is drawn in and relatively
+lowered; so that on reaching a coast with a shelving
+shore the form of the surface consists of a trough in
+front followed by an advancing crest. These effects
+may be observed on a small scale in the case of a
+steamship advancing up a river, or into a harbour
+with a narrow channel, but are inappreciable in deep
+water, or along a precipitous open coast.</p>
+
+<p>(<i>e.</i>) <i>The Earthquake of Lisbon, 1755.</i>&mdash;The disastrous
+results of a submarine earthquake upon the
+coast have never been more terribly illustrated than
+in the case of the earthquake of Lisbon which took
+place on November 1, 1755. The inhabitants had no
+warning of the coming danger, when a sound like
+that of thunder was heard underground, and immediately
+afterwards a violent shock threw down the
+greater part of their city; this was the land-wave. In the
+course of about six minutes, sixty thousand persons
+perished. The sea first retired and left the harbour dry,
+so forming the trough in front of the crest; immediately
+after the water rolled in with a lofty crest, some 50
+feet above the ordinary level, flooding the harbour and
+portions of the city bordering the shore. The mountains
+of Arrabida, Estrella, Julio, Marvan, and Cintra,
+were impetuously shaken, as it were, from their very
+foundations; and according to the computation of
+Humboldt, a portion of the earth's surface four times
+the extent of Europe felt the effects of this great
+seismic shock, which extended to the Alps, the shores
+of the Baltic, the lakes of Scotland, the great lakes of
+<span class="pagenum"><a name="Page_222" id="Page_222">[Pg 222]</a></span>North America, and the West Indian Islands. The
+velocity of the sea-wave was estimated at about 20
+miles per minute.</p>
+
+<p>(<i>f.</i>) <i>Earthquake of Lima and Callao, 28th October,
+1746.</i>&mdash;Of somewhat similar character was the terrible
+catastrophe with which the cities of Lima and Callao
+were visited in the middle of the last century,<a name="FNanchor_6_178" id="FNanchor_6_178"></a><a href="#Footnote_6_178" class="fnanchor">[6]</a> in
+which the former city, then one of great magnificence,
+was overthrown; and Callao was inundated by
+a sea-wave, in which out of 23 ships of all sizes in the
+harbour the greater number foundered; several, including
+a man-of-war, were lifted bodily and stranded,
+and all the inhabitants with the exception of about
+two hundred were drowned. A volcano in Lucanas
+burst forth the same night, and such quantities of
+water descended from the cone that the whole
+country was overflowed; and in the mountain near
+Pataz, called Conversiones de Caxamarquilla, three
+other volcanoes burst forth, and torrents of water
+swept down their sides. In the case of these cities,
+the land-wave, or shock, preceded the sea-wave, which
+of course only reached the port of Callao.</p>
+
+<p><span class="pagenum"><a name="Page_223" id="Page_223">[Pg 223]</a></span></p>
+
+<div class="figcenter">
+<a name="FIGURE_37">
+  <img src="images/figure37.jpg" alt="Isoseismal curves" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 37.</span>&mdash;The lines represent isoseismal curves, or curves of equal
+intensity, the force decreasing outwards from the focus at Charleston,
+No. 10.
+</td></tr>
+</table>
+</div>
+
+<p>(<i>g.</i>) <i>Earthquake of Charleston, 31st August, 1886.</i>&mdash;I
+shall close this account of some remarkable earthquakes
+with a few facts regarding that of Charleston,
+on the Atlantic seaboard of Carolina.<a name="FNanchor_7_179" id="FNanchor_7_179"></a><a href="#Footnote_7_179" class="fnanchor">[7]</a> At 9.51 a.m.
+of this day, the inhabitants engaged in their ordinary
+occupations were startled by the sound of a distant
+roar, which speedily deepened in volume so as to resemble
+the noise of cannon rattling along the road,
+"spreading into an awful noise, that seemed to pervade
+at once the troubled earth below and the still air
+above." At the same time the floors began to heave
+underfoot, the walls visibly swayed to and fro, and the
+crash of falling masonry was heard on all sides, while
+<span class="pagenum"><a name="Page_224" id="Page_224">[Pg 224]</a></span>universal terror took possession of the populace, who
+rushed into the streets, the black portion of the community
+being the most demonstrative of their terror.
+Such was the commencement of the earthquake, by
+which nearly all the houses of Charleston were damaged
+or destroyed, many of the public buildings seriously
+injured or partially demolished. The effects were felt
+all over the States as far as the great lakes of Canada
+and the borders of the Rocky Mountains. Two
+epicentral <i>foci</i> appear to have been established; one
+lying about 15 miles to the N.W. of Charleston, called
+the <i>Woodstock focus</i>; the other about 14 miles due
+west of Charleston, called the <i>Rantowles focus</i>;
+around each of these <i>foci</i> the isoseismic curves concentrated,<a name="FNanchor_8_180" id="FNanchor_8_180"></a><a href="#Footnote_8_180" class="fnanchor">[8]</a>
+but in the map (<a href="#FIGURE_37">Fig. 37</a>) are combined
+into the area of one curve. The position of these <i>foci</i>
+clearly shows that the origin of the Charleston earthquake
+was not submarine, though occurring within a
+short distance of the Atlantic border; the curves of
+equal intensity (isoseismals) are drawn all over the
+area influenced by the shock.</p>
+
+<p>As a general result of these detailed observations,
+Captain Dutton states that there is a remarkable
+coincidence in the phenomena with those indicated by
+the theory of wave-motion as the proper one for an
+elastic, nearly homogeneous, solid medium, composed
+of such materials as we know to constitute the rocks
+of the outer portions of the earth; but on the other
+hand he states that nothing has been disclosed which
+seems to bring us any nearer to the precise nature of
+the forces which generated the disturbance.<a name="FNanchor_9_181" id="FNanchor_9_181"></a><a href="#Footnote_9_181" class="fnanchor">[9]</a></p>
+
+<div class="footnote"><p><a name="Footnote_1_173" id="Footnote_1_173"></a><a href="#FNanchor_1_173"><span class="label">[1]</span></a> The views of Mr. R. Mallet, briefly stated, are somewhat as
+follows:&mdash;Owing to the secular cooling of the earth, and the consequent
+lateral crushing of the surface, this crushing from time to
+time overcomes the resistance; in which case shocks are experienced
+along the lines of fracture and faulting by which the crust is intersected.
+These shocks give rise to earthquake waves, and as the crushing of the
+walls of the fissure developes heat, we have here the <i>vera causa</i> both of
+volcanic eruptions and earthquake shocks&mdash;the former intensified into
+explosions by access of water through the fissures.&mdash;"On the Dynamics
+of Earthquakes," <i>Trans. Roy. Irish Acad.</i>, vol. xxi.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_174" id="Footnote_2_174"></a><a href="#FNanchor_2_174"><span class="label">[2]</span></a> Illustration of the mode of propagation of earthquake shocks will
+be found in Lyell's <i>Principles of Geology</i>, vol. ii. p. 136, or in the
+author's <i>Physiography</i>, p. 76, after Hopkins.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_175" id="Footnote_3_175"></a><a href="#FNanchor_3_175"><span class="label">[3]</span></a> "Rep. on Theories of Elevation and Earthquakes," <i>Brit. Ass.
+Rep.</i> 1847, p. 33. In the map prepared by Prof. J. Milne and Mr. W.
+K. Burton to show the range of the great earthquake of Japan (1891),
+similar isoseismal lines are laid down.</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_176" id="Footnote_4_176"></a><a href="#FNanchor_4_176"><span class="label">[4]</span></a> Lyell, <i>loc. cit.</i>, p. 163. Two Catalogues of Earthquakes have been
+drawn up by Prof. O'Reilly, and are published in the <i>Trans. Roy. Irish
+Academy</i>, vol. xxviii. (1884 and 1886).</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_177" id="Footnote_5_177"></a><a href="#FNanchor_5_177"><span class="label">[5]</span></a> <i>Ninth Annual Report, U.S. Geological Survey</i> (1888).</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_178" id="Footnote_6_178"></a><a href="#FNanchor_6_178"><span class="label">[6]</span></a> <i>A True and Particular Account of the Dreadful Earthquake</i>, 2nd
+edit. The original published at Lima by command of the Viceroy.
+London, 1748. Translated from the Spanish.</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_179" id="Footnote_7_179"></a><a href="#FNanchor_7_179"><span class="label">[7]</span></a> I take the account from that of Capt. Dutton above cited, <a href="#Page_220">p. 220</a>.</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_180" id="Footnote_8_180"></a><a href="#FNanchor_8_180"><span class="label">[8]</span></a> Dutton, <i>Report</i>, Plate xxvi., p. 308.</p></div>
+
+<div class="footnote"><p><a name="Footnote_9_181" id="Footnote_9_181"></a><a href="#FNanchor_9_181"><span class="label">[9]</span></a> <i>Ibid.</i>, p. 211. On the connection between the moon's position and
+earthquake shocks, see Mr. Richardson's paper on Scottish earthquakes,
+<i>Trans. Edin. Geol. Soc.</i>, vol. vi. p. 194 (1892).</p></div>
+<p><span class="pagenum"><a name="Page_225" id="Page_225">[Pg 225]</a></span></p>
+
+
+<hr class="major" />
+<h1><a name="PART_VII" id="PART_VII"></a>PART VII.
+<br /><br />
+VOLCANIC AND SEISMIC PROBLEMS.</h1>
+
+
+
+<hr class="major" />
+<h2><a name="PART_VII_CHAPTER_I" id="PART_VII_CHAPTER_I"></a>CHAPTER I.
+<br /><br />
+THE ULTIMATE CAUSE OF VOLCANIC ACTION.</h2>
+
+
+<p>Volcanic phenomena are the outward manifestations
+of forces deep-seated beneath the crust of the
+globe; and in seeking for the causes of such phenomena
+we must be guided by observation of their
+nature and mode of action. The universality of these
+phenomena all over the surface of our globe, in past
+or present times, indicates the existence of a general
+cause beneath the crust. It is true that there are
+to be found large tracts from which volcanic rocks
+(except those of great geological antiquity) are
+absent, such as Central Russia, the Nubian Desert,
+and the Central States of North America; but such
+absence by no means implies the non-existence of
+the forces which give rise to volcanic action beneath
+those regions, but only that the forces have not been
+sufficiently powerful to overcome the resistance offered
+by the crust over those particular tracts. On the
+other hand, the similarity of volcanic lavas over wide
+regions is strong evidence that they are drawn from
+<span class="pagenum"><a name="Page_226" id="Page_226">[Pg 226]</a></span>one continuous magma, consisting of molten matter
+beneath the solid exterior crust.</p>
+
+<p>(<i>a.</i>) <i>Lines of Volcanic Action.</i>&mdash;It has been shown in a
+previous page that volcanic action of recent or Tertiary
+times has taken place mainly along certain lines which
+may be traced on the surface of a map or globe. One
+of these lines girdles the whole globe, while others lie
+in certain directions more or less coincident with lines
+of flexure, plication or faulting. The Isle of Sumatra
+offers a remarkable example of the coincidence of
+such lines with those of volcanic vents. Not only the
+great volcanic cones, but also the smaller ones, are
+disposed in chains which run parallel to the longitudinal
+axis of the island (N.W.-S.E.). The sedimentary
+rocks are bent and faulted in lines parallel
+to the main axis, and also to the chains of volcanic
+mountains, and the observation holds good with
+regard to different geological periods.<a name="FNanchor_1_182" id="FNanchor_1_182"></a><a href="#Footnote_1_182" class="fnanchor">[1]</a> Another
+remarkable case is that of the Jordan Valley. Nowhere
+can the existence of a great fracture and
+vertical displacement of the strata be more clearly
+determined than along this remarkable line of depression;
+and it is one which is also coincident with a
+zone of earthquake and volcanic disturbances.</p>
+
+<p>(<i>b.</i>) <i>Such Lines generally lie along the Borders of the
+Ocean.</i>&mdash;But even where, from some special cause,
+actual observation on the relations of the strata are
+precluded, the general configuration of the ground
+and the relations of the boundaries between land and
+sea to those of volcanic chains, evidently point in
+many cases to their mutual interdependence. The
+remarkable straightness of the coast of Western
+<span class="pagenum"><a name="Page_227" id="Page_227">[Pg 227]</a></span>America, and of the parallel chain of the Andes,
+affords presumptive evidence that this line is coincident
+with a fracture or system of faults, along which
+the continent has been bodily raised out of the waters
+of the ocean. Of this elevation within very recent times
+we have abundant evidence in the existence of raised
+coral-reefs and oceanic shell-beds at intervals all along
+the coast; rising in Peru to a level of no less than
+3,000 feet above the ocean, as shown by Alexander
+Agassiz.<a name="FNanchor_2_183" id="FNanchor_2_183"></a><a href="#Footnote_2_183" class="fnanchor">[2]</a> Such elevations probably occurred at a
+time when the volcanoes of the Andes were much
+more active than at present. Considered as a whole,
+these great volcanic mountains may be regarded as
+in a dormant, or partially moribund, condition; and
+if the volcanic forces have to some extent lost their
+strength, so it would appear have those of elevation.</p>
+
+<p>(<i>c.</i>) <i>Areas of Volcanic Action in the British Isles.</i>&mdash;In
+the case of the British Islands it may be observed
+that the later Tertiary volcanic districts lie along
+very ancient depressions, which may indicate zones
+of weakness in the crust. Thus the Antrim plateau,
+as originally constituted, lay in the lap of a range of
+hills formed of crystalline, or Lower Silurian, rocks;
+while the volcanic isles of the Inner Hebrides were
+enclosed between the solid range of the Archæan
+rocks of the Outer Hebrides on the one side, and the
+Silurian and Archæan ranges of the mainland on
+the other. And if we go back to the Carboniferous
+period, we find that the volcanic district of the centre
+of Scotland was bounded by ranges of solid strata
+both to the north and south, where the resistance to
+interior pressure from molten matter would have
+been greater than in the Carboniferous hollow-ground,
+<span class="pagenum"><a name="Page_228" id="Page_228">[Pg 228]</a></span>where such molten matter has been abundantly extruded.
+In all these cases, the outflow of molten
+matter was in a direction somewhat parallel to the
+plications of the strata.</p>
+
+<p>(<i>d.</i>) <i>Special Conditions under which the Volcanic
+Action operates.</i>&mdash;Assuming, then, that the molten
+matter, forming an interior magma or shell, is constantly
+exerting pressure against the inner surface of
+the solid crust, and can only escape where the crust
+is too weak (owing to faults, plications, or fissures) to
+resist the pressure, we have to inquire what are the
+special conditions under which outbursts of volcanic
+matter take place, and what are the general results
+as regards the nature of the <i>ejecta</i> dependent on
+those conditions.</p>
+
+<p>(<i>e.</i>) <i>Effect of the Presence or Absence of Water.</i>&mdash;The
+two chief conditions determining the nature of
+volcanic products, considered in the mass, are the
+presence or absence of water. Such presence or
+absence does not of course affect the essential
+chemical composition of the <i>ejecta</i>, but it materially
+influences the form in which the matter is erupted.
+The agency of water in volcanic eruptions is a very
+interesting and important subject in connection with
+the history of volcanic action, and has been ably
+treated by Professor Prestwich.<a name="FNanchor_3_184" id="FNanchor_3_184"></a><a href="#Footnote_3_184" class="fnanchor">[3]</a> At one time it was
+considered that water was essential to volcanic
+activity; and the fact that the great majority of
+volcanic cones are situated in the vicinity of the
+oceanic waters, or of inland seas, was pointed to in
+confirmation of this theory. But the existence in
+Western America and other volcanic countries of
+fissures of eruption along which molten lava has been
+<span class="pagenum"><a name="Page_229" id="Page_229">[Pg 229]</a></span>extruded without explosions of steam, shows that
+water is not an essential factor in the production of
+volcanic phenomena; and, as Professor Prestwich has
+clearly demonstrated, it is to be regarded as an element
+in volcanic explosions, rather than as a prime cause
+of volcanic action. The main difficulty he shows to
+be thermo-dynamical; and calculating the rate of
+increase in the elastic force of steam on descending
+to greater and greater depths and reaching strata
+of higher and higher temperatures, as compared with
+the force of capillarity, he comes to the conclusion
+that water cannot penetrate to depths of more than
+seven or eight miles, and therefore cannot reach the
+seat of the eruptive forces. Professor Prestwich also
+points out that if the extrusion of lava were due to
+the elastic force of vapour of water there should be a
+distinct relation between the discharge of the lava
+and of the vapour; whereas the result of an examination
+of a number of well-recorded eruptions shows that
+the two operations are not related, and are, in fact,
+perfectly independent. Sometimes there has been a
+large discharge of lava, and little or no escape of
+steam; at other times there have been paroxysmal
+explosive eruptions with little discharge of lava.
+Even in the case of Vesuvius, which is close to the sea,
+there have been instances when the lava has welled
+out almost with the tranquillity of a water-spring.</p>
+
+<p>(<i>f.</i>) <i>Access of Surface Water to Molten Lava during
+Eruptions.</i>&mdash;The existence of water during certain
+stages in eruptions is too frequent a phenomena to
+be lost sight of; but its presence may be accounted
+for in other ways, besides proximity to the sea or
+ocean. Certain volcanic mountains, such as Etna
+and Vesuvius, are built upon water-bearing strata,
+<span class="pagenum"><a name="Page_230" id="Page_230">[Pg 230]</a></span>receiving their supplies from the rainfall of the surrounding
+country, or perhaps partly from the sea.
+In addition to this the ashes and scoriæ of the
+mountain sides are highly porous, and rain or snow
+can penetrate and settle downwards around the pipe
+or throat through which molten lava wells up from
+beneath. In such cases it is easy to understand how,
+at the commencement of a period of activity, molten
+lava ascending through one or more fissures, and
+meeting with water-charged strata or scoriæ, will convert
+the water into steam at high pressure, resulting
+in explosions more or less violent and prolonged, in
+proportion to the quantity of water and the depth
+to which it has penetrated. In this manner we may
+suppose that ashes, scoriæ, and blocks of rock torn
+from the sides of the crater-throat, and hurled into
+the air, are piled around the vent, and accumulate into
+hills or mountains of conical form. After the explosion
+has exhausted itself, the molten lava quietly
+wells up and fills the crater, as in the cases of those of
+Auvergne and Syria, and other places. We may,
+therefore, adopt the general principle that in volcanic
+eruptions <i>where water in large quantities is present, we
+shall have crater-cones built up of ashes, scoriæ, and
+pumice; but where absent, the lava will be extravasated
+in sheets to greater or less distances without the formation
+of such cones; or if cones are fanned, they will
+be composed of solidified lava only, easily distinguishable
+from crater-cones of the first class</i>.</p>
+
+<p>(<i>g.</i>) <i>Nature of the Interior Reservoir from which
+Lavas are derived.</i>&mdash;We have now to consider the
+nature of the interior reservoir from which lavas are
+derived, and the physical conditions necessary for
+their eruption at the surface.</p>
+
+<p><span class="pagenum"><a name="Page_231" id="Page_231">[Pg 231]</a></span></p><p>Without going back to the question of the original
+condition of our globe, we may safely hold the view
+that at a very early period of geological history it
+consisted of a solidified crust at a high temperature,
+enfolding a globe of molten matter at a still higher
+temperature. As time went on, and the heat
+radiated into space from the surface of the globe,
+while at the same time slowly ascending from the
+interior by conduction, the crust necessarily contracted,
+and pressing more and more on the interior
+molten magma, this latter was forced from time to
+time to break through the contracting crust along
+zones of weakness or fissures.</p>
+
+<p>(<i>h.</i>) <i>The Earth's Crust in a State of both Exterior
+Thrust and of Interior Tension.</i>&mdash;As has been shown
+by Hopkins,<a name="FNanchor_4_185" id="FNanchor_4_185"></a><a href="#Footnote_4_185" class="fnanchor">[4]</a> and more recently by Mr. Davison,<a name="FNanchor_5_186" id="FNanchor_5_186"></a><a href="#Footnote_5_186" class="fnanchor">[5]</a> an
+exterior crust in such a condition must eventually
+result in being under a state of horizontal thrust
+towards the exterior and of tension towards the
+interior surface. For the exterior portion, having
+cooled down, and consequently contracted to its
+normal state, will remain rigid up to a certain point
+of resistance; but the interior portion still continuing
+to contract, owing to the conduction of the heat
+towards the exterior, would tend to enter upon a
+condition of tension, as becoming too small for the interior
+molten magma; and such a state of tension would
+tend to produce rupture of the interior part. In this
+manner fissures would be formed into which the
+molten matter would enter; and if the fissures happened
+to extend to the surface, owing to weakness of
+the crust or flexuring of the strata, or other cause, the
+<span class="pagenum"><a name="Page_232" id="Page_232">[Pg 232]</a></span>molten matter would be extruded either in the form
+of dykes or volcanic vents. In this way we may
+account for the numerous dykes of trap by which
+some volcanic districts are intersected, such as those
+of the north of Ireland and centre of Scotland.</p>
+
+<p>From the above considerations, it follows that the
+earth's crust must be in a condition both of pressure
+(or lateral thrust) towards the exterior portion, and
+of tension towards the interior, the former condition
+resulting in faulting and flexuring of the rocks, the
+latter in the formation of open fissures, through which
+lava can ascend under high pressure. These operations
+are of course the attempt of the natural forces
+to arrive at a condition of equilibrium, which is never
+attained because the processes are never completed;
+in other words, radiation and convection of heat are
+constantly proceeding, giving rise to new forces of
+thrust and tension.</p>
+
+<p>It now remains for us to consider what may be the
+condition of the interior molten magma; and in doing
+so we must be guided to a large extent by considerations
+regarding the nature of the extruded matter at
+the surface.</p>
+
+<p>(<i>i.</i>) <i>Relative Densities of Lavas.</i>&mdash;Now, observation
+shows that, as bearing on the subject under consideration,
+lavas occur mainly under two classes as regards
+their density. The most dense (or basic) are those in
+which silica is deficient, but iron is abundant; the
+least dense (or acid) are those which are rich in silica,
+but in which iron occurs in small quantity. This
+division corresponds with that proposed by Bunsen
+and Durocher<a name="FNanchor_6_187" id="FNanchor_6_187"></a><a href="#Footnote_6_187" class="fnanchor">[6]</a> for volcanic rocks, upon the results of
+analyses of a large number of specimens from various
+districts. Rocks may be thus arranged in groups:</p>
+<p><span class="pagenum"><a name="Page_233" id="Page_233">[Pg 233]</a></span></p>
+
+<blockquote style="margin-left:10em; text-indent:-6em;"><p>(1) <i>The Basic</i> (Heavier)&mdash;poor in silica, rich in iron; containing
+silica 45-58 per cent. Examples:
+Basalt, Dolerite, Hornblende rock, Diorite,
+Diabase, Gabbro, Melaphyre, and Leucite
+lava.</p>
+
+<p>(2) <i>The Acid</i> (Lighter)&mdash;rich in silica, poor in iron; containing
+silica 62-78 per cent. Examples:
+Trachyte, Rhyolite, Obsidian, Domite, Felsite,
+Quartz-porphyry, Granite.</p></blockquote>
+
+<p>The Andesite group forms a connecting link between
+the highly acid and the basic groups, and there are
+many varieties of the above which it is not necessary
+to enumerate. Durocher supposes that the molten
+magmas of these various rocks are arranged in concentric
+shells within the solid crust in order of their
+respective densities, those of the lighter density,
+namely the acid magmas, being outside those of
+greater density, namely the basic; and this is a view
+which seems not improbable from a consideration not
+only of the principle itself, but of the succession of
+the varieties of lava in many districts. Thus we find
+that acid lavas have been generally extruded first, and
+basic afterwards&mdash;as in the cases of Western America,
+of Antrim, the Rhine and Central France. And
+if the interior of our globe had been in a condition
+of equilibrium from the time of the consolidation
+of the crust to the present, reason would
+induce us to conclude that the lavas would ultimately
+have arranged themselves in accordance with the
+conditions of density beneath that crust. But the
+state of equilibrium has been constantly disturbed.
+Every fresh outburst of volcanic force, and every fresh
+extrusion of lava, tends to disturb it, and to alter the
+relations of the interior viscous or molten magmas.
+Owing to this it happens, as we may suppose, that the
+<span class="pagenum"><a name="Page_234" id="Page_234">[Pg 234]</a></span>order of eruption according to density is sometimes
+broken, and we find such rocks as granophyre (a
+variety of andesite) breaking through the plateau-basalts
+of Mull and Skye, as explained in a former
+chapter. Notwithstanding such variations, however,
+the view of Durocher may be considered as the most
+reasonable we can arrive at on a subject which is
+confessedly highly conjectural.</p>
+
+<p>(<i>j.</i>) <i>Conclusion as regards the Ultimate Cause of
+Volcanic Action</i>.&mdash;Notwithstanding, however, the complexity
+of the subject, and the uncertainties which
+must attend an inquiry where some of the data are outside
+the range of our observation, sufficient evidence
+can be adduced to enable us to arrive at a tolerably
+clear view of the ultimate cause of volcanic action.
+So tempting a subject was sure to evoke numerous
+essays, some of great ingenuity, such as that of Mr.
+Mallet; others of great complexity, such as that of
+Dr. Daubeny. But more recent consideration and
+wider observation have tended to lead us to the conclusion
+that the ultimate cause is the most simple, the
+most powerful, and the most general which can be
+suggested; namely, <i>the contraction of the crust due to
+secular cooling of the more deeply seated parts by conduction
+and radiation of heat into space</i>. Owing to
+this cause, the enclosed molten matter is more or less
+abundantly extruded from time to time along the
+lines and vents of eruption, so as to accommodate itself
+to the ever-contracting crust. Nor can we doubt that
+this process has been going on from the very earliest
+period of the earth's history, and formerly at a greater
+rate than at present. When the crust was more
+highly heated, the radiation and conduction must
+have been proportionately more rapid. Owing to
+<span class="pagenum"><a name="Page_235" id="Page_235">[Pg 235]</a></span>this cause also the contraction of the crust was
+accelerated. To such irresistible force we owe
+the wonderful flexuring, folding, and horizontal
+overthrusting which the rocks have undergone in
+some portions of the globe&mdash;such as in the Alps, the
+Highlands of Scotland and of Ireland, and the Alleghannies
+of America. It is easy to show that the
+acceleration of the earth's rotation must be a consequence
+of such contraction; but, after all, this is but
+one of those compensatory forces of which we see
+several examples in the world around us. It can also
+be confidently inferred that at an early period of the
+earth's history, when the moon was nearer to our
+planet than at present, the tides were far more powerful,
+and their effect in retarding the earth's rotation
+was consequently greater. During this period the
+acceleration due to contraction was also greater; and
+the two forces probably very nearly balanced each
+other. Both these forces (those of acceleration and
+retardation) have been growing weaker down to the
+present day, though there appears to have been a
+slight advantage on the side of the retarding force.<a name="FNanchor_7_188" id="FNanchor_7_188"></a><a href="#Footnote_7_188" class="fnanchor">[7]</a></p>
+
+<div class="footnote"><p><a name="Footnote_1_182" id="Footnote_1_182"></a><a href="#FNanchor_1_182"><span class="label">[1]</span></a> R. D. M. Verbeek, <i>Krakatau</i>, p. 105 (1886); also, J. Milne, <i>The
+Great Earthquake of Japan</i>, 1891.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_183" id="Footnote_2_183"></a><a href="#FNanchor_2_183"><span class="label">[2]</span></a> <i>Bull. Mus. Comp. Zool.</i>, vol. iii.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_184" id="Footnote_3_184"></a><a href="#FNanchor_3_184"><span class="label">[3]</span></a> <i>Proc. Roy. Soc.</i>, No. 237 (1885); also, <i>Rep. Brit. Assoc.</i> (1881).</p></div>
+
+<div class="footnote"><p><a name="Footnote_4_185" id="Footnote_4_185"></a><a href="#FNanchor_4_185"><span class="label">[4]</span></a> Hopkins, <i>supra cit.</i>, <a href="#Page_218">p. 218</a>.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_186" id="Footnote_5_186"></a><a href="#FNanchor_5_186"><span class="label">[5]</span></a> C. Davison and G. H. Darwin, <i>Phil. Trans.</i>, vol. 178, p; 241.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_187" id="Footnote_6_187"></a><a href="#FNanchor_6_187"><span class="label">[6]</span></a> Durocher, <i>Ann. des Mines</i>, vol. ii. (1857).</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_188" id="Footnote_7_188"></a><a href="#FNanchor_7_188"><span class="label">[7]</span></a> See on this subject the author's <i>Textbook of Physiography</i> (Deacon
+and Co., 1888), pp. 56 and 122.</p></div>
+<p><span class="pagenum"><a name="Page_236" id="Page_236">[Pg 236]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_VII_CHAPTER_II" id="PART_VII_CHAPTER_II"></a>CHAPTER II.
+<br /><br />
+LUNAR VOLCANOES.</h2>
+
+
+<p>The surface of the moon presented to our view affords
+such remarkable indications of volcanic phenomena
+of a special kind, that we are justified in devoting a
+chapter to their consideration. It is very tantalising
+that our beautiful satellite only permits us to look at
+and admire one half of her sphere; but it is not a very
+far-fetched inference if we feel satisfied that the other
+half bears a general resemblance to that which is presented
+to the earth. It is scarcely necessary to inform
+the reader why it is that we never see but one face;
+still, for the sake of those who have not thought out
+the subject I may state that it is because the moon
+rotates on her axis exactly in the time that she performs
+a revolution round the earth. If this should
+not be sufficiently clear, let the reader perform a very
+simple experiment for himself, which will probably
+bring conviction to his mind that the explanation here
+given is correct. Let him place an orange in the
+centre of a round table, and then let him move
+round the table from a starting-point sideways, ever
+keeping his face directed towards the orange; and
+when he has reached his starting-point, he will find
+that he has rotated once round while he has performed
+one revolution round the table. In this case the performer
+<span class="pagenum"><a name="Page_237" id="Page_237">[Pg 237]</a></span>represents the moon and the orange the
+earth.</p>
+
+<p>Now this connection between the earth and her
+satellite is sufficiently close to be used as an argument
+(if not as actual demonstration) that the earth and
+the moon were originally portions of the same mass,
+and that during some very early stage in the development
+of the solar system these bodies parted company,
+to assume for ever after the relations of planet and
+satellite. At the epoch referred to, we may also suppose
+that these two masses of matter were in a highly
+incandescent, if not even gaseous, state; and we conclude,
+therefore, that having been once portions of the
+same mass, they are composed of similar materials.
+This conclusion is of great importance in enabling us
+to reason from analogy regarding the origin of the
+physical features on the moon's surface, and for the
+purpose of comparison with those which we find on
+the surface of our globe; because it is evident that, if
+the composition of the moon were essentially different
+from that of our earth, we should have no basis whatever
+for a comparison of their physical features.</p>
+
+<p>When the moon started on her career of revolution
+round the earth, we may well suppose that her orbit was
+much smaller than at present. She was influenced by
+counteracting forces, those of gravitation drawing her
+towards the centre of gravity of the earth,<a name="FNanchor_1_189" id="FNanchor_1_189"></a><a href="#Footnote_1_189" class="fnanchor">[1]</a> and the
+centrifugal force, which in the first instance was the
+stronger, so that her orbit for a lengthened period
+gradually increased until the two forces, those of
+<span class="pagenum"><a name="Page_238" id="Page_238">[Pg 238]</a></span>attraction and repulsion, came into a condition of
+equilibrium, and she now performs her revolution
+round the earth at a mean distance of 240,000 miles,
+in an orbit which is only very slightly elliptical.<a name="FNanchor_2_190" id="FNanchor_2_190"></a><a href="#Footnote_2_190" class="fnanchor">[2]</a> How
+the period of the moon's rotation is regulated by the
+earth's attraction on her molten lava-sheets, first at the
+surface, and now probably below the outer crust, has
+been graphically shown by Sir Robert Ball,<a name="FNanchor_3_191" id="FNanchor_3_191"></a><a href="#Footnote_3_191" class="fnanchor">[3]</a> but it
+cannot be doubted that once the moon was appreciably
+nearer to our globe than at present. The attraction of
+her mass produced tides in the ocean of correspondingly
+greater magnitude, and capable of effecting
+results, both in eroding the surface and in transporting
+masses of rock, far beyond the bounds of our
+every-day experience.</p>
+
+<p>Of all the heavenly bodies, the sun excepted, the
+moon is the most impressive and beautiful. As we
+catch her form, rising as a fair crescent in the western
+sky after sunset, gradually increasing in size and
+brilliancy night after night till from her circular disk
+she throws a full flood of light on our world and then
+passes through her decreasing phases, we recognise
+her as "the Governor of the night," or in the words
+of our own poet, when in her crescent phase, "the
+Diadem of night." Seen through a good binocular glass,
+her form gains in rotundity; but under an ordinary
+telescope with a four-inch objective, she appears like a
+globe of molten gold. Yet all this light is derivative,
+and is only a small portion of that she receives from
+the sun. That her surface is a mass of rigid matter
+destitute of any inherent brilliancy, appears plain
+<span class="pagenum"><a name="Page_239" id="Page_239">[Pg 239]</a></span>enough when we view a portion of her disk through
+a very large telescope. It was the good fortune of
+the author to have an opportunity for such a view
+through one of the largest telescopes in the world.
+The 27-inch refractor manufactured by Sir Howard
+Grubb of Dublin, for the Vienna observatory, a few
+years ago, was turned on a portion of the moon's
+disk before being finally sent off to its destination;
+and seen by the aid of such enormous magnifying
+power, nothing could be more disappointing as regards
+the appearance of our satellite. The sheen and lustre
+of the surface was now observed no longer; the mountains
+and valleys, the circular ridges and hollows
+were, indeed, wonderfully defined and magnified, but
+the matter of which they seemed to be constituted
+resembled nothing so much as the pale plaster of a
+model. One could thus fully realise the fact that the
+moon's light is only derivative. Still we must recollect
+that the most powerful telescope can only bring
+the surface of the moon to a distance from us of
+about 250 miles; and it need not be said that objects
+seen at such a distance on our earth present very
+deceptive appearances; so that we gain little information
+regarding the composition of the moon's crust,
+or exterior surface, simply from observation by the aid
+of large telescopes.</p>
+
+<p>Reasoning from analogy with our globe, we may
+infer that the exterior shell of the moon consists of
+crystalline volcanic matter of the highly silicated, or
+acid, varieties resting upon another of a denser description,
+rich in iron, and resembling basalt. This
+hypothesis is hazarded on the supposition that the
+composition of the matter of the moon's mass resembles
+in the main that of our globe. During the
+<span class="pagenum"><a name="Page_240" id="Page_240">[Pg 240]</a></span>process of cooling from a molten condition, the heavier
+lavas would tend to fall inwards, and allow the lighter
+to come to the surface, and form the outer shell in
+both cases. Thus, the outer crust would resemble the
+trachytic lavas of our globe, and their pale colour
+would enable the sun's rays to be reflected to a greater
+extent than if the material were of the blackness of
+basalt.<a name="FNanchor_4_192" id="FNanchor_4_192"></a><a href="#Footnote_4_192" class="fnanchor">[4]</a> So much for the material. We have now to
+consider the structure of the moon's surface, and here
+we find ourselves treading on less speculative and
+safer ground. All astronomers since the time of
+Schroter seem to be of accord in the opinion that the
+remarkable features of the moon's surface are in some
+measure of volcanic origin, and we shall presently
+proceed to consider the character of these forms more
+in detail.</p>
+
+<p>But first, and as leading up to the discussion of
+these physical features, we must notice one essential
+difference between the constitution of the moon and
+of the earth; namely, the absence of water and of an
+atmosphere in the case of the moon. The sudden and
+complete occultation of the stars when the moon's disk
+passes between them and the place of the observer on
+the earth's surface, is sufficient evidence of the absence
+of air; and, as no cloud has ever been noticed to veil
+even for a moment any part of our satellite's face, we
+are pretty safe in concluding that there is no water;
+or at least, if there be any, that it is inappreciable in
+<span class="pagenum"><a name="Page_241" id="Page_241">[Pg 241]</a></span>quantity.<a name="FNanchor_5_193" id="FNanchor_5_193"></a><a href="#Footnote_5_193" class="fnanchor">[5]</a> Hence we infer that there is no animal or
+vegetable life on the moon's surface; neither are there
+oceans, lakes or rivers, snowfields or glaciers, river-valleys
+or cañons, islands, stratified rocks, nor volcanoes
+of the kind most prevalent on our own
+globe.</p>
+
+<div class="figcenter">
+<a name="FIGURE_38"></a>
+<a href="images/figure38full.jpg">
+  <img src="images/figure38.jpg" alt="Photograph of the Moon" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 38.</span>&mdash;Photograph of the moon's surface (in part) showing the
+illuminated "spots," and ridges, and the deep hollows. The position
+of "Tycho" is shown near the upper edge, and some of the volcanic
+craters are very clearly seen near the margin.
+</td></tr>
+</table>
+</div>
+
+<p><span class="pagenum"><a name="Page_242" id="Page_242">[Pg 242]</a></span></p><p>Now on looking at a photographic picture of the
+moon's surface (<a href="#FIGURE_38">Fig. 38</a>), we observe that there are
+enormous dark spaces, irregular in outline, but more or
+less approaching the circular form, surrounded by steep
+and precipitous declivities, but with sides sloping outwards.
+These were supposed at one time to be seas;
+and they retain the name, though it is universally
+admitted that they contain no water. Some of these
+hollows are four English miles in depth. The largest
+of these, situated near the north pole of the moon, is
+called <i>Mare Imbrium</i>; next to it is <i>Mare Serenitatis</i>;
+next, <i>Mare Tranquilitatis</i>, with several others.<a name="FNanchor_6_194" id="FNanchor_6_194"></a><a href="#Footnote_6_194" class="fnanchor">[6]</a> Mare
+Imbrium is of great depth, and from its floor rise
+several conical mountains with circular craters, the
+largest of which, <i>Archimedes</i>, is fifty miles in diameter;
+its vast smooth interior being divided into seven
+distinct zones running east and west. There is no
+central mountain or other obvious internal sign of
+former volcanic activity, but its irregular wall rises
+into abrupt towers, and is marked outside by decided
+terraces.<a name="FNanchor_7_195" id="FNanchor_7_195"></a><a href="#Footnote_7_195" class="fnanchor">[7]</a></p>
+
+<p>The Mare Imbrium is bounded along the east by a
+range of mountains called the <i>Apennines</i>, and towards
+the north by another range called the <i>Alps</i>; while a
+third range, that of the <i>Caucasus</i>, strikes northward
+from the junction of the two former ranges. Several
+<span class="pagenum"><a name="Page_243" id="Page_243">[Pg 243]</a></span>circular or oval craters are situated on, and near to,
+the crest of these ridges.</p>
+
+<div class="figcenter">
+<a name="FIGURE_39">
+  <img src="images/figure39.jpg" alt="Portion of the Moon" />
+</a>
+<table border="0" summary="" style="max-width:80%;">
+<tr><td align="left">
+<span class="smcap">Fig. 39.</span>&mdash;A magnified portion of the moon's surface, showing the
+forms of the great craters with their outer ramparts. The white spot
+with shadow is a cone rising from the centre of one of the larger craters
+to a great height and thus becoming illuminated by the sun's light.
+</td></tr>
+</table>
+</div>
+
+<p>But the greater part of the moon's hemisphere is
+dotted over by almost innumerable circular crater-like
+hollows; sometimes conspicuously surmounting lofty
+conical mountains, at other times only sinking below
+the general outer surface of the lunar sphere. On
+approaching the margin, these circular hollows appear
+oval in shape owing to their position on the sphere;
+and the general aspect of those that are visible leads
+to the conclusion that there are large numbers of
+smaller craters too small to be seen by the most
+powerful telescopes. These cones and craters are
+<span class="pagenum"><a name="Page_244" id="Page_244">[Pg 244]</a></span>the most characteristic objects on the whole of the
+visible surface, and when highly magnified present
+very rugged outlines, suggestive of slag, or lava,
+which has consolidated on cooling, as in the case of
+most solidified lava-streams on our earth.<a name="FNanchor_8_196" id="FNanchor_8_196"></a><a href="#Footnote_8_196" class="fnanchor">[8]</a> One of
+the most remarkable of these crateriform mountains
+is that named <i>Copernicus</i>, situated in a line with the
+southern prolongation of the Apennines. Of this
+mountain Sir R. Ball says: "It is particularly well
+known through Sir John Herschel's drawing, so
+beautifully reproduced in the many editions of the
+<i>Outlines of Astronomy</i>. The region to the west is
+dotted over with innumerable minute craterlets. It
+has a central, many-peaked mountain about 2,400
+feet in height. There is good reason to believe that
+the terracing shown in its interior is mainly due to
+the repeated alternate rise, partial congealation and
+retreat of a vast sea of lava. At full moon it is
+surrounded by radiating streaks."<a name="FNanchor_9_197" id="FNanchor_9_197"></a><a href="#Footnote_9_197" class="fnanchor">[9]</a> The view regarding
+the structure of Copernicus here expressed is of
+importance, as it is probably applicable to all the
+craters of our satellite.</p>
+
+<p>"When the moon is five or six days old," says Sir
+Robert Ball, "a beautiful group of three craters will
+be readily found on the boundary line between night
+and day. These are <i>Catharina</i>, <i>Cyrillus</i>, and <i>Theophilus</i>.
+Catharina is the most southerly of the group,
+and is more than 16,000 feet deep and connected to
+Cyrillus by a wide valley; but between Cyrillus and
+Theophilus there is no such connection. Indeed
+Cyrillus looks as if its huge surrounding ramparts,
+as high as Mont Blanc, had been completely finished
+<span class="pagenum"><a name="Page_245" id="Page_245">[Pg 245]</a></span>when the volcanic forces commenced the formation of
+Theophilus, the rampart of which encroaches considerably
+on its older neighbour. Theophilus stands
+as a well-defined round crater, about 64 miles in
+diameter, with an internal depth of 14,000 to 18,000
+feet, and a beautiful central group of mountains, one-third
+of that height, on its floor. This proves that the
+last eruptive efforts in this part of the moon fully
+equalled in intensity those that had preceded them.
+Although Theophilus is on the whole the deepest
+crater we can see in the moon, it has received little
+or no deformation by secondary eruptions."</p>
+
+<p>But perhaps the most remarkable object on the
+whole hemisphere of the moon is "the majestic
+Tycho," which rises from the surface near the south
+pole, and at a distance of about 1/6th of the diameter
+of the sphere from its margin. Its depth is stated by
+Ball to be 17,000 feet, and its diameter 50 miles.
+But its special distinction amongst the other volcanic
+craters lies in the streaks of light which radiate from
+it in all directions for hundreds and even thousands of
+miles, stretching with superb indifference across vast
+plains, into the deepest craters, and over the highest
+opposing ridges. When the sun rises on Tycho these
+streaks are invisible, but as soon as it has reached a
+height of 25° to 30° above the horizon, the rays emerge
+from their obscurity, and gradually increase in brightness
+until full moon, when they become the most conspicuous
+objects on her surface. As yet no satisfactory
+explanation has been given of the origin of these illuminated
+rays,<a name="FNanchor_10_198" id="FNanchor_10_198"></a><a href="#Footnote_10_198" class="fnanchor">[10]</a> but I may be permitted to add that their
+form and mode of occurrence are eminently suggestive
+of gaseous exhalations from the volcano illumined by
+<span class="pagenum"><a name="Page_246" id="Page_246">[Pg 246]</a></span>the sun's rays; and owing to the absence of an
+atmosphere, spreading themselves out in all directions
+and becoming more and more attenuated until they
+cease to be visible.</p>
+
+<p>The above account will probably suffice to give the
+reader a general idea of the features and inferential
+structure of the moon's surface. That she was once
+a molten mass is inferred from her globular form;
+but, according to G. F. Chambers, the most delicate
+measurements indicate no compression at the poles.<a name="FNanchor_11_199" id="FNanchor_11_199"></a><a href="#Footnote_11_199" class="fnanchor">[11]</a>
+That her surface has cooled and become rigid is also
+a necessary inference; though Sir J. Herschel considered
+that the surface still retains a temperature
+<i>possibly</i> exceeding that of boiling water.<a name="FNanchor_12_200" id="FNanchor_12_200"></a><a href="#Footnote_12_200" class="fnanchor">[12]</a> However
+this may be, it is pretty certain that whatever changes
+may occur upon her surface are not due to present
+volcanic action, all evidence of such action being
+admittedly absent. If, when the earth and moon
+parted company, their respective temperatures were
+equal, the moon being so much the smaller of the
+two would have cooled more rapidly, and the surface
+may have been covered by a rigid crust when as yet
+that of the earth may have been molten from heat.
+Hence the rigidity of the moon's surface may date
+back to an immensely distant period, but she may
+still retain a high temperature within this crust.
+Having arrived at this stage of our narrative, we are
+in a position to consider by what means, and under
+what conditions, the cones and craters which diversify
+the lunar surface have been developed.</p>
+
+<p>In doing so it may be desirable, in the first place, to
+determine what form of crater on our earth's surface
+those of the moon do not represent; and we are
+<span class="pagenum"><a name="Page_247" id="Page_247">[Pg 247]</a></span>guided in our inquiry by the consideration of the
+absence of water on the lunar surface. Now there
+are large numbers of crateriform mountains on our
+globe in the formation of which water has played an
+important, indeed essential, part. As we have already
+seen, water, though not the ultimate cause of volcanic
+eruptions, has been the chief agent, when in the form
+of steam at high pressure, in producing the explosions
+which accompany these eruptions, and in tearing up
+and hurling into the air the masses of rock, scoriæ,
+and ashes, which are piled around the vents of eruption
+in the form of craters during periods of activity.
+To this class of craters those of Etna, Vesuvius, and
+Auvergne belong. These mountains and conical hills
+(the domes excepted) are all built up of accumulations
+of fragmental material, with occasional sheets
+and dykes of lava intervening; and where eruptions
+have taken place in recent times, observation has
+shown that they are accompanied by outbursts of
+vast quantities of aqueous vapour, which has been the
+chief agent (along with various gases) in piling up the
+circular walls of the crater.</p>
+
+<p>It has also been shown that in many instances
+these crater-walls have been breached on one side,
+and that streams of molten lava which once occupied
+the cup to a greater or less height, have poured down
+the mountain side. Hence the form or outline of
+many of these fragmental craters is crescent-shaped.
+Such breached craters are to be found in all parts of
+the world, and are not confined to any one district, or
+even continent, so that they may be considered as
+characteristic of the class of volcanic crater-cones to
+which I am now referring. In the case of the moon,
+however, we fail to observe any decided instances
+<span class="pagenum"><a name="Page_248" id="Page_248">[Pg 248]</a></span>of breached craters, with lava-streams, such as those
+I have described.<a name="FNanchor_13_201" id="FNanchor_13_201"></a><a href="#Footnote_13_201" class="fnanchor">[13]</a> In nearly all cases the ramparts
+appear to extend continuously round the enclosed
+depression, solid and unbroken; or at least with no
+large gap occupying a very considerable section of the
+circumference. (See <a href="#FIGURE_38">Fig. 38</a>.) Hence we are led to
+suspect that there is some essential distinction between
+the craters on the surface of the moon and the greater
+number of those on the surface of our earth.</p>
+
+<p>It is scarcely necessary to add that the volcanic
+mountains of the moon offer no resemblance whatever
+to the dome-shaped volcanic mountains of our
+globe. If it were otherwise, the lunar mountains
+would appear as simple luminous points rising from a
+dark floor, over which they would cast a conical
+shadow. But the form of the lunar volcanic mountains
+is essentially different; as already observed,
+they consist in general of a circular rampart enclosing
+a depressed floor, sometimes terraced as in the case of
+Copernicus, from which rise one or more conical
+mountains, which are in effect the later vents of
+eruption.</p>
+
+<p>In our search, therefore, for analogous forms on our
+own earth, we must leave out the craters and domes
+of the type furnished by the European volcanoes and
+their representatives abroad, and have recourse to
+others of a different type. Is there then, we may ask,
+any type of volcanic mountain on our globe comparable
+with those on the moon? In all probability
+there is.</p>
+
+<p>If the reader will turn to the description of the
+<span class="pagenum"><a name="Page_249" id="Page_249">[Pg 249]</a></span>volcanoes of the Hawaiian group in the Pacific,
+especially that of Mauna Loa, as given by Professor
+Dana and others, and compare it with that of Copernicus,
+he will find that in both cases we have a
+circular rampart of solid lava enclosing a vast plain
+of the same material from which rise one or more
+lava-cones. The interiors in both cases are terraced.
+So that, allowing for differences in magnitude, it would
+seem that there is no essential distinction between
+lunar craters and terrestrial craters of the type of
+Mauna Loa. Dana calls these Hawaiian volcanoes
+"basaltic," basalt being the prevalent material of
+which they are formed. Those of the moon may be
+composed of similar material, or otherwise; but in
+either case we may suppose they are built up of
+lava, erupted from vents connected with the molten
+reservoirs of the interior. Thus we conclude that they
+belong to an entirely different type, and have been
+built up in a different manner, from those represented
+by Etna, Vesuvius, and most of the extinct volcanoes
+of Auvergne, the Eifel, and of other districts considered
+in these pages.</p>
+
+<p>Let us now endeavour to picture to ourselves the
+stages through which the moon may be supposed to
+have passed from the time her surface began to consolidate
+owing to the radiation of her heat into space;
+for there is every probability that some of the craters
+now visible on her disk were formed at a very early
+period of her physical history.</p>
+
+<p>When the surface began to consolidate, it must
+also have contracted; and the interior molten matter,
+pressed out by the contracting crust, must have been
+over and over again extruded through fissures produced
+over the solidified surface, until the solid crust
+<span class="pagenum"><a name="Page_250" id="Page_250">[Pg 250]</a></span>extended over the whole lunar surface, and became
+of considerable thickness.</p>
+
+<p>It is from this epoch that, in all probability, we
+should date the commencement of what may be
+termed "the volcanic history" of the moon. We
+must bear in mind that although the moon's surface
+had become solid, its temperature may have remained
+high for a very long period. But the continuous
+radiation of the surface-heat into space would produce
+continuous contraction, while the convection of the
+interior heat would tend to increase the thickness of
+the outer solid shell; and this, ever pressing with
+increasing force on the interior molten mass, would
+result in frequent ruptures of the shell, and the extrusion
+of molten lava rising from below. Hence we
+may suppose the fissure-eruptions of lava were of
+frequent occurrence for a lengthened period during
+the early stage of consolidation of the lunar crust; but
+afterwards these may be supposed to have given place
+to eruptions through pipes or vents, resulting in the
+formation of the circular craters which form such
+striking and characteristic objects in the physical
+aspect of our satellite.<a name="FNanchor_14_202" id="FNanchor_14_202"></a><a href="#Footnote_14_202" class="fnanchor">[14]</a></p>
+
+<p>It is not to be supposed that the various physical
+features on the lunar surface have all originated in
+the same way. The great ranges of mountains previously
+described may have originated by a process
+of piling up of immense masses of molten lava
+extruded from the interior through vents or fissures;
+while the great hollows (or "seas") are probably
+<span class="pagenum"><a name="Page_251" id="Page_251">[Pg 251]</a></span>due to the falling inwards of large spaces owing to
+the escape of the interior lava.</p>
+
+<p>But it is with the circular craters that we are most
+concerned. Judging from analogy with the lava-craters
+present on our globe, we must suppose them
+to be due to the extrusion, and piling up, of lava
+through central pipes, followed in some cases by
+the subsidence of the floor of the crater. It seems
+not improbable that it was in this way the greater
+number of the circular craters lying around Tycho,
+and dotting so large a space round the margin of
+the moon, were constructed. (See <a href="#FIGURE_38">Fig. 38</a>.) In
+general they appear to consist of an elevated rim,
+enclosing a depressed plain, out of which a central
+cone arises. The rim may be supposed to have been
+piled up by successive discharges of lava from a
+central orifice; and after the subsidence of the
+paroxysm the lava still in a molten condition may
+have sunk down, forming a seething lake within the
+vast circular rampart, as in the case of the Hawaiian
+volcanoes. The terraces observable within the craters
+in some instances have probably been left by subsequent
+eruptions which have not attained to the level
+of preceding ones; and where a central crater-cone is
+seen to rise within the caldron, we may suppose this
+to have been built up by a later series of eruptions of
+lava through the original pipe after the consolidation
+of the interior sea of lava. The mamelons of the
+Isle of Bourbon,<a name="FNanchor_15_203" id="FNanchor_15_203"></a><a href="#Footnote_15_203" class="fnanchor">[15]</a> and some of the lava-cones of
+Hawaii, appear to offer examples on our earth's
+surface of these peculiar forms.</p>
+
+<p>Such are the views of the origin of the physical
+<span class="pagenum"><a name="Page_252" id="Page_252">[Pg 252]</a></span>features of our satellite which their form and inferred
+constitution appear to suggest. They are not offered
+with any intention of dogmatising on a subject
+which is admittedly obscure, and regarding which
+we have by no means all the necessary data for
+coming to a clear conclusion. All that can be
+affirmed is, that there is a great deal to be said in
+support of them, and that they are to some extent in
+harmony with phenomena within range of observation
+on the surface of our earth.</p>
+
+<p>The far greater effects of lunar vulcanicity, as compared
+with those of our globe, may be accounted for
+to some extent by the consideration that the force of
+gravity on the surface of the moon is only one-sixth
+of that on the surface of the earth. Hence the
+eruptive forces of the interior of our satellite have
+had less resistance to overcome than in the case of
+our planet; and the erupted materials have been shot
+forth to greater distances, and piled up in greater
+magnitude, than with us. We have also to recollect
+that the abrading action of water has been absent
+from the moon; so that, while accumulations of matter
+had been proceeding throughout a prolonged period
+over its surface, there was no counteracting agency
+of denudation at work to modify or lessen the effects
+of the ruptive forces.</p>
+
+<div class="footnote"><p><a name="Footnote_1_189" id="Footnote_1_189"></a><a href="#FNanchor_1_189"><span class="label">[1]</span></a> Correctly speaking, each attracts the other towards its centre of
+gravity with a force proportionate to its mass, and inversely as the
+square of the distance; but the earth being by much the larger body,
+its attraction is far greater than that of the moon.</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_190" id="Footnote_2_190"></a><a href="#FNanchor_2_190"><span class="label">[2]</span></a> The variation in the distance is only under rare circumstances
+40,000 miles, but ordinarily about 13,000 miles.</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_191" id="Footnote_3_191"></a><a href="#FNanchor_3_191"><span class="label">[3]</span></a> <i>Story of the Heavens</i>, 2nd edition, p. 525, <i>et seq.</i></p></div>
+
+<div class="footnote"><p><a name="Footnote_4_192" id="Footnote_4_192"></a><a href="#FNanchor_4_192"><span class="label">[4]</span></a> A series of researches made by Zöllner, of Leipzig, led him to
+assign to the light-reflecting capacity of the full-moon a result intermediate
+between that obtained by Bouguer, which gave a brightness equal
+to 1/300000 part of that of the sun, and of Wollaston, which gave 1/801070
+part. We may accept 1/618000 of Zöllner as sufficiently close; so that it
+would require 600,000 full moons to give the same amount of light as
+that of the sun.</p></div>
+
+<div class="footnote"><p><a name="Footnote_5_193" id="Footnote_5_193"></a><a href="#FNanchor_5_193"><span class="label">[5]</span></a> Schroter, however, came to the conclusion that the moon has an
+atmosphere.</p></div>
+
+<div class="footnote"><p><a name="Footnote_6_194" id="Footnote_6_194"></a><a href="#FNanchor_6_194"><span class="label">[6]</span></a> A chart of the moon's surface, with the names of the principal
+physical features, will be found in Ball's <i>Story of the Heavens</i>, 2nd
+edit., p. 60. It must be remembered that the moon as seen through a
+telescope appears in reversed position.</p></div>
+
+<div class="footnote"><p><a name="Footnote_7_195" id="Footnote_7_195"></a><a href="#FNanchor_7_195"><span class="label">[7]</span></a> <i>Ibid.</i>, p. 66.</p></div>
+
+<div class="footnote"><p><a name="Footnote_8_196" id="Footnote_8_196"></a><a href="#FNanchor_8_196"><span class="label">[8]</span></a> As represented by Nasmyth's models in plaster.</p></div>
+
+<div class="footnote"><p><a name="Footnote_9_197" id="Footnote_9_197"></a><a href="#FNanchor_9_197"><span class="label">[9]</span></a> Ball, <i>loc. cit.</i>, p. 67.</p></div>
+
+<div class="footnote"><p><a name="Footnote_10_198" id="Footnote_10_198"></a><a href="#FNanchor_10_198"><span class="label">[10]</span></a> Ball, <i>loc. cit.</i>, p. 69.</p></div>
+
+<div class="footnote"><p><a name="Footnote_11_199" id="Footnote_11_199"></a><a href="#FNanchor_11_199"><span class="label">[11]</span></a> <i>Astronomy</i>, p. 78.</p></div>
+
+<div class="footnote"><p><a name="Footnote_12_200" id="Footnote_12_200"></a><a href="#FNanchor_12_200"><span class="label">[12]</span></a> <i>Outlines of Astronomy</i>, p. 285.</p></div>
+
+<div class="footnote"><p><a name="Footnote_13_201" id="Footnote_13_201"></a><a href="#FNanchor_13_201"><span class="label">[13]</span></a> At rare intervals a few crescent-shaped ridges are discernible on the
+lunar sphere, but it is very doubtful if they are to be regarded as
+breached craters.</p></div>
+
+<div class="footnote"><p><a name="Footnote_14_202" id="Footnote_14_202"></a><a href="#FNanchor_14_202"><span class="label">[14]</span></a> The number of "spots" on the moon was considered to be 244
+until Schroter increased it to 6,000, and accurately described many of
+them. Schroter seems to have been the earliest observer who identified
+the circular hollows on the moon's surface as volcanic craters.</p></div>
+
+<div class="footnote"><p><a name="Footnote_15_203" id="Footnote_15_203"></a><a href="#FNanchor_15_203"><span class="label">[15]</span></a> Drawings of these very curious forms are given by Judd, <i>Volcanoes</i>,
+p. 127.</p></div>
+<p><span class="pagenum"><a name="Page_253" id="Page_253">[Pg 253]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="PART_VII_CHAPTER_III" id="PART_VII_CHAPTER_III"></a>CHAPTER III.
+<br /><br />
+ARE WE LIVING IN AN EPOCH OF SPECIAL
+VOLCANIC ACTIVITY?</h2>
+
+
+<p>The question which we are about to discuss in the
+concluding chapter of this volume is one to which we
+ought to be able to offer a definite answer. This
+can only be arrived at by a comparison of the violence
+and extent of volcanic and seismic phenomena within
+the period of history with those of pre-historic periods.</p>
+
+<p>At first sight we might be disposed to give to the
+question an affirmative reply when we remember the
+eruptions of the last few years, and add to these the
+volcanic outbursts and earthquake shocks which
+history records. The cases of the earthquake and
+eruption in Japan of November, 1891, where in one
+province alone two thousand people lost their lives
+and many thousand houses were levelled<a name="FNanchor_1_204" id="FNanchor_1_204"></a><a href="#Footnote_1_204" class="fnanchor">[1]</a>; that of
+Krakatoa, in 1883; of Vesuvius, in 1872; and many
+others of recent date which might be named, added
+to those which history records;&mdash;the recollection of
+such cases might lead us to conclude that our epoch
+is one in which the subterranean volcanic forces had
+broken out with extraordinary energy over the earth's
+<span class="pagenum"><a name="Page_254" id="Page_254">[Pg 254]</a></span>surface. Still, when we come to examine into the cases
+of recorded eruptions&mdash;especially those of great violence&mdash;we
+find that they are limited to very special districts;
+and even if we extend our retrospect into the
+later centuries of our era, we shall find that the exceptionally
+great eruptions have been confined to certain
+permanently volcanic regions, such as the chain of
+the Andes, that of the Aleutian, Kurile, Japanese, and
+Philippine and Sunda Islands, lying for the most part
+along the remarkable volcanic girdle of the world to
+which I have referred in a previous page. Add to
+these the cases of Iceland and the volcanic islands of
+the Pacific, and we have almost the whole of the very
+active volcanoes of the world.</p>
+
+<p>Then for the purposes of our inquiry we have to
+ascertain how these active vents of eruption compare,
+as regards the magnitude of their operations,
+with those of the pre-historic and later Tertiary
+times. But before entering into this question it maybe
+observed, in the first place, that a large number of
+the vents of eruption, even along the chain of the
+earth's volcanic girdle, are dormant or extinct. This
+observation applies to many of the great cones and
+domes of the Andes, including Chimborazo and other
+colossal mountains in Ecuador, Columbia, Chili, Peru,
+and Mexico. The region between the eastern Rocky
+Mountains and the western coast of North America
+was, as we have seen, one over which volcanic eruptions
+took place on a vast scale in later Tertiary
+times; but one in which only the after-effects of
+volcanic action are at present in operation. We have
+also seen that the chain of volcanoes of Japan and of
+the Kurile Islands are only active to a slight extent
+as compared with former times, and the same observation
+<span class="pagenum"><a name="Page_255" id="Page_255">[Pg 255]</a></span>applies to those of New Zealand. Out of 130
+volcanoes in the Japanese islands, only 48 are now
+believed to be active.</p>
+
+<p>Again, if we turn to other districts we have been
+considering, we find that in the Indian Peninsula, in
+Arabia, in Syria and the Holy Land, in Persia, in
+Abyssinia and Asia Minor&mdash;regions where volcanic
+operations were exhibited on a grand scale throughout
+the Tertiary period, and in some cases almost
+down into recent times&mdash;we are met by similar evidences
+either of decaying volcanic energy, or of an
+energy which, as far as surface phenomena are concerned,
+is a thing of the past. Lastly, turning our
+attention to the European area, notwithstanding the
+still active condition of Etna, Vesuvius, and a few
+adjoining islands, we see in all directions throughout
+Southern Italy evidences of volcanic operations of a
+past time,&mdash;such as extinct crater-cones, lakes occupying
+the craters of former volcanoes, and extensive
+deposits of tuff or streams of lava&mdash;all concurring in
+giving evidence of a period now past, when vulcanicity
+was widespread over regions where its presence is
+now never felt except when some earthquake shock,
+like that of the Riviera, brings home to our minds the
+fact that the motive force is still beneath our feet,
+though under restrained conditions as compared with
+a former period.</p>
+
+<p>Similar conclusions are applicable with even greater
+force to other parts of the European area. The region
+of the Lower Rhine and Moselle, of Hungary and the
+Carpathians, of Central France, of the North of Ireland
+and the Inner Hebrides, all afford evidence of
+volcanic operations at a former period on an extensive
+scale; and the contrast between the present physically
+<span class="pagenum"><a name="Page_256" id="Page_256">[Pg 256]</a></span>silent and peaceful condition of these regions, as
+regards any outward manifestations of sub-terrestrial
+forces, compared with those which were formerly
+prevalent, cannot fail to impress our minds irresistibly
+with the idea that volcanic energy has well-nigh exhausted
+itself over these tracts of the earth's surface.</p>
+
+<p>From this general survey of the present condition
+of the earth's surface, as regards the volcanic operations
+going on over it, and a comparison with those
+of a preceding period, we are driven to the conclusion
+that, however violent and often disastrous are the
+volcanic and seismic phenomena of the present day,
+they are restricted to comparatively narrow limits;
+and that even within these limits the volcanic forces
+are less powerful than they were in pre-historic times.</p>
+
+<p>The middle part of the Tertiary period appears,
+in fact, to have been one of extraordinary volcanic
+activity, whether we regard the wide area over which
+this activity manifested itself, or the results as shown
+by the great amount of the erupted materials. Many
+of the still active volcanic chains, or groups, probably
+had their first beginnings at the period referred to;
+but in the majority of cases the eruptive forces have
+become dormant or extinct. With the exception of
+the lavas of the Indian-Peninsular area, which appear,
+at least partially, to belong to the close of the Cretaceous
+epoch, the specially volcanic period may
+be considered to extend from the beginning of the
+Miocene down to the close of the Pliocene stage.
+During the Eocene stage, volcanic energy appears to
+have been to a great degree dormant; but plutonic
+energy was gathering strength for the great effort of
+the Miocene epoch, when the volcanic forces broke
+out with extraordinary violence over Europe, the
+<span class="pagenum"><a name="Page_257" id="Page_257">[Pg 257]</a></span>British Isles, and other regions, and continued to
+develop throughout the succeeding Pliocene epoch,
+until the whole globe was surrounded by a girdle of
+fire.</p>
+
+<hr class="tb" />
+
+<p>The reply, therefore, to the question with which we
+set out is very plain; and is to the effect that the
+present epoch is one of comparatively low volcanic
+activity. The further question suggests itself, whether
+the volcanic phenomena of the middle Tertiary period
+bear any comparison with those of past geological
+times. This, though a question of great interest, is one
+which is far too large to be discussed here; and it is
+doubtful if we have materials available upon which to
+base a conclusion. But it may be stated with some
+confidence, in general terms, that the history of the
+earth appears to show that, throughout all geological
+time, our world has been the theatre of intermittent
+geological activity, periods of rest succeeding those of
+action; and if we are to draw a conclusion regarding
+the present and future, it would be that, owing to the
+lower rate of secular cooling of the crust, volcanic
+action ought to become less powerful as the world
+grows older.</p>
+
+<div class="footnote"><p><a name="Footnote_1_204" id="Footnote_1_204"></a><a href="#FNanchor_1_204"><span class="label">[1]</span></a> Admirably illustrated in Prof. J. Milne's recently published work,
+<i>The Great Earthquake of Japan, 1891</i>.</p></div>
+
+<p><span class="pagenum"><a name="Page_259" id="Page_259">[Pg 259]</a></span></p>
+
+<hr class="major" />
+<h2><a name="APPENDIX" id="APPENDIX"></a>APPENDIX.
+<br /><br />
+A BRIEF ACCOUNT OF THE PRINCIPAL VARIETIES
+OF VOLCANIC ROCKS.</h2>
+
+
+<p>The text-books on this subject are so numerous and accessible,
+that a very brief account of the volcanic rocks is all that need
+be given here for the purposes of reference by readers not
+familiar with petrological details.</p>
+
+<p>Let it be observed, in the first place, that there is no hard and
+fast line between the varieties of igneous and volcanic rocks.
+In this as in other parts of creation&mdash;<i>natura nil facit per
+saltum</i>; there are gradations from one variety to the other.
+At the same time a systematic arrangement is not only desirable,
+but necessary; and the most important basis of arrangement
+is that founded on the proportion of <i>silica</i> (or quartz) in
+the various rocks, as first demonstrated by Durocher and
+Bunsen, who showed that silica plays the same part in the
+inorganic kingdom that carbon does in the organic. Upon this
+hypothesis, which is a very useful one to work with, these
+authors separated all igneous and volcanic rocks into two
+classes, viz., the Basic and the Acid; the former containing
+from 45-58 per cent., the latter 62-78 per cent. of that mineral.
+But there are a few intermediate varieties which serve to bridge
+over the space between the Basic and Acid Groups. The following
+is a generalised arrangement of the most important rocks
+under the above heads:&mdash;</p>
+
+<p class="center"><i>Tabular View of Chief Igneous and Volcanic Rocks.</i></p>
+
+<div class="center">
+<table border="0" cellpadding="0" cellspacing="0" summary="">
+<tr><td align="center">
+<span class="smcap">Basic Group.</span></td></tr>
+<tr><td align="left">
+&nbsp;1. Basalt and Dolerite.</td></tr>
+<tr><td align="left">
+&nbsp;2. Gabbro.</td></tr>
+<tr><td align="left">
+<span class="pagenum"><a name="Page_260" id="Page_260">[Pg 260]</a></span>&nbsp;3. Diorite.</td></tr>
+<tr><td align="left">
+&nbsp;4. Diabase and Melaphyre.</td></tr>
+<tr><td align="left">
+&nbsp;5. Porphyrite.</td></tr>
+<tr><td align="center" style="height:2em;">
+<span class="smcap">Intermediate Group.</span></td></tr>
+<tr><td align="left">
+&nbsp;6. Syenite.</td></tr>
+<tr><td align="left">
+&nbsp;7. Mica-trap, or Lampophyre.</td></tr>
+<tr><td align="left">
+&nbsp;8. Andesite.</td></tr>
+<tr><td align="center" style="height:2em;">
+<span class="smcap">Acid Group.</span></td></tr>
+<tr><td align="left">
+&nbsp;9. Trachyte, Domite, and Phonolite.</td></tr>
+<tr><td align="left">
+10. Rhyolite and Obsidian.</td></tr>
+<tr><td align="left">
+11. Granophyre.</td></tr>
+<tr><td align="left">
+12. Granite.</td></tr>
+</table>
+</div>
+
+<p>In the above grouping, and in the following definitions, I have
+not been able to follow any special authority. But the most serviceable
+text-books are those of Mr. Frank Rutley, <i>Study of
+Rocks</i>, and Dr. Hatch, <i>Petrology</i>; also H. Rosenbusch, <i>Mikroskopische
+Physiographie der Mineralien</i>, and F. Zirkel's <i>Untersuchungen
+über mikroskopische Structur der Basaltgesteine</i>. We
+shall consider these in the order above indicated:&mdash;</p>
+
+<p>1. <span class="smcap">Basalt.</span>&mdash;The most extensively distributed of all volcanic
+rocks. It is a dense, dark rock of high specific gravity (2.4-2.8),
+consisting of plagioclase felspar (Labradorite or anorthite),
+augite, and titano-ferrite (titaniferous magnetite). Olivine is
+often present; and when abundant the rock is called "olivine-basalt."
+In the older rocks, basalt has often undergone decomposition
+into melaphyre; and amongst the metamorphic rocks
+it has been changed into diorite or hornblende rock; the augite
+having been converted into hornblende.</p>
+
+<p>When leucite or nepheline replaces plagioclase, the rock
+becomes a leucite-basalt,<a name="FNanchor_1_205" id="FNanchor_1_205"></a><a href="#Footnote_1_205" class="fnanchor">[1]</a> or nepheline-basalt. Some basalts
+have a glass paste, or "ground-mass," in which the minerals
+are enclosed.</p>
+
+<p>The lava of Vesuvius may be regarded as a variety of basalt
+in which leucite replaces plagioclase, although this latter mineral
+<span class="pagenum"><a name="Page_261" id="Page_261">[Pg 261]</a></span>is also present. Zirkel calls it "Sanidin-leucitgestein," as both
+the macroscopic and microscopic structure reveal the presence
+of leucite, sanidine, plagioclase, nephiline, augite, mica, olivine,
+apatite, and magnetite.<a name="FNanchor_2_206" id="FNanchor_2_206"></a><a href="#Footnote_2_206" class="fnanchor">[2]</a></p>
+
+<p><i>Dolerite</i> does not differ essentially from basalt in composition
+or structure, but is a largely crystalline-granular variety,
+occurring more abundantly than basalt amongst the more
+ancient rocks, and the different minerals are distinctly visible
+to the naked eye.</p>
+
+<p>A remarkable variety of this rock occurs at Slieve Gullion in
+Ireland, in which mica is so abundant as to constitute the rock
+a "micaceous dolerite."</p>
+
+<p>2. <span class="smcap">Gabbro.</span>&mdash;A rather wide group of volcanic rocks with
+variable composition. Essentially it is a crystalline-granular
+compound of plagioclase, generally Labradorite and diallage.
+Sometimes the pyroxenic mineral becomes hypersthene, giving
+rise to <i>hypersthene-gabbro</i>; or when hornblende is present, to
+<i>hornblende-gabbro</i>; when olivine, to <i>olivine-gabbro</i>. Magnetite
+is always present.</p>
+
+<p>These rocks occur in the Carlingford district in Ireland, in
+the Lizard district of Cornwall, the Inner Hebrides (Mull,
+Skye, etc.) of Scotland, and in Saxony.</p>
+
+<p>3. <span class="smcap">Diorite.</span>&mdash;A crystalline-granular compound of plagioclase
+and hornblende with magnetite. When quartz is present it
+becomes (according to the usual British acceptation) a <i>syenite</i>;
+but this view is gradually giving place to the German definition
+of syenite, which is a compound of orthoclase and hornblende;
+and it may be better to denominate the variety as <i>quartz-diorite</i>.
+The diorites are abundant as sheets and dykes amongst
+the older palæozoic and metamorphic rocks, and are sometimes
+exceedingly rich in magnetite. Mica, epidote, and chlorite are
+also present as accessories.</p>
+
+<p>The rock occurs in North Wales, Charnwood Forest, Wicklow,
+Galway, and Donegal, and the Highlands of Scotland.
+There can be little doubt that amongst the metamorphic rocks
+of Galway, Mayo, and Donegal the great beds of (often columnar)
+diorite were originally augitic lavas, which have since undergone
+transformation.</p>
+
+<p><span class="pagenum"><a name="Page_262" id="Page_262">[Pg 262]</a></span></p><p>4. <span class="smcap">Diabase.</span>&mdash;It is very doubtful if "Diabase" ought to be
+regarded as a distinct species of igneous rock, as it seems to be
+simply an altered variety of basalt or dolerite, in which chlorite,
+a secondary alteration-product, has been developed by the decomposition
+of the pyroxene or olivine of the original rock. It
+is a convenient name for use in the field when doubt occurs as
+to the real nature of an igneous rock. Melaphyre is a name
+given to the very dark varieties of altered augitic lavas, rich in
+magnetite and chlorite.</p>
+
+<p>5. <span class="smcap">Porphyrite</span> (or quartzless porphyry).&mdash;A basic variety of
+felstone-porphyry, consisting of a felspathic base with distinct
+crystals of felspar, with which there may be others of hornblende,
+mica, or augite. The colour is generally red or purple,
+and it weathers into red clay, in contrast to the highly acid or
+silicated felsites which weather into whitish sand.</p>
+
+<p>6. <span class="smcap">Syenite.</span>&mdash;As stated above, this name has been variously
+applied. Its derivation is from Syene (Assouan) in Egypt, and
+the granitic rocks of that district were called "syenites," under
+the supposition (now known to be erroneous) that they differ from
+ordinary granites in that they were supposed to be composed of
+quartz, felspar, and hornblende, instead of quartz, felspar, and
+mica. From this it arose that syenite was regarded as a variety of
+granite in which the mica is replaced by hornblende, and this
+has generally been the British view of the question. But the
+German definition is applied to an entirely different rock,
+belonging to the felstone family; and according to this classification
+syenite consists of a crystalline-granular compound of
+orthoclase and hornblende, in which quartz may or may not be
+present. From this it will be seen that, according to Zirkel,
+syenite is essentially distinct from diorite in the species of its
+felspar.<a name="FNanchor_3_207" id="FNanchor_3_207"></a><a href="#Footnote_3_207" class="fnanchor">[3]</a> It seems desirable to adopt the German view; and as
+regards diorites containing quartz as an accessory, to apply to
+them the name of <i>quartz-diorite</i>, as stated above, the name
+syenite as used by British geologists having arisen from a
+misconception.</p>
+
+<p>7. <span class="smcap">Mica-trap (Lampophyre).</span>&mdash;A rock, allied to the felstone
+family, in which mica is an abundant and essential constituent,
+thus consisting of plagioclase and mica, with a little magnetite.
+Quartz may be an accessory. This rock occurs amongst the
+<span class="pagenum"><a name="Page_263" id="Page_263">[Pg 263]</a></span>Lower Silurian strata of Ireland, Cumberland, and the South of
+Scotland; it is not volcanic in the ordinary acceptation of that
+term. The term <i>lampophyre</i> was introduced by Gümbel in
+describing the mica-traps of Fichtelgebirge.</p>
+
+<p>8. <span class="smcap">Andesite.</span>&mdash;This is a dark-coloured, compact or vesicular,
+semi-vitreous group of volcanic rocks, composed essentially
+of a glassy plagioclase felspar, and a ferro-magnesian
+constituent enclosed in a glassy base. According to the nature
+of the ferro-magnesian constituent, the group may be divided into
+<i>hornblende-andesite</i>, <i>biotite-andesite</i>, and <i>augite-andesite</i>. Quartz
+is sometimes present, and when this mineral becomes an essential
+it gives rise to a variety called <i>quartz-andesite</i> or <i>dacite</i>.</p>
+
+<p>These rocks are the principal constituents of the lavas of the
+Andes, and the name was first applied to them by Leopold von
+Buch; but their representatives also occur in the British Isles,
+Germany, and elsewhere. Dacite is the lava of Krakatoa and
+some of the volcanoes of Japan.</p>
+
+<p>9, 10. <span class="smcap">Trachyte</span> and <span class="smcap">Domite</span>, etc.&mdash;These names include very
+numerous varieties of highly silicated volcanic rock, and in their
+general form consist of a white felsitic paste with distinct
+crystals of sanidine, together with plagioclase, augite, biotite,
+hornblende, and accessories. When crystalline grains or blebs
+of quartz occur, we have a quartz-trachyte; when tridymite is
+abundant, as in the trachyte of Co. Antrim, we have "tridymite-trachyte."</p>
+
+<p>The trachytes occupy a position between the pitchstone lavas
+on the one hand, and the andesites and granophyres on the
+other.</p>
+
+<p>(<i>b.</i>) <i>Domite</i> is the name applied to the trachytic rocks of the
+Auvergne district and the Puy de Dôme particularly. They do
+not contain free quartz, though they are highly acid rocks, containing
+sometimes as much as 68 per cent. of silica.</p>
+
+<p>(<i>c.</i>) <i>Phonolite (Clinkstone)</i> is a trachytic rock, composed
+essentially of sanidine, nepheline, and augite or hornblende.
+It is usually of a greenish colour, hard and compact, so as
+to ring under the hammer; hence the name. The Wolf Rock
+is composed of phonolite, and it occurs largely in Auvergne.</p>
+
+<p>(<i>d.</i>) <i>Rhyolites</i> are closely connected with the <i>quartz-trachytes</i>,
+but present a marked fluidal, spherulitic, or perlitic structure.
+They consist of a trachytic ground-mass in which grains or
+<span class="pagenum"><a name="Page_264" id="Page_264">[Pg 264]</a></span>crystals of quartz and sanidine, with other accessory minerals,
+are imbedded. They occur amongst the volcanic rocks of the
+British Isles, Hungary, and the Lipari Islands, from which the
+name <i>Liparite</i> has been derived.</p>
+
+<p>(<i>e.</i>) <i>Obsidian (Pitchstone).</i>&mdash;This is a vitreous, highly acid
+rock, which has become a volcanic glass in consequence of
+rapid cooling, distinct minerals not having had time to
+form. It has a conchoidal fracture, various shades of colour
+from grey to black; and under the microscope is seen to contain
+crystallites or microliths, often beautifully arranged in stellate or
+feathery groups. Spherulitic structure is not infrequent; and
+occasionally a few crystals of sanidine, augite, or hornblende
+are to be seen imbedded in the glassy ground-mass. The rock
+occurs in dykes and veins in the Western Isles of Scotland, in
+Antrim, and on the borders of the Mourne Mountains, near
+Newry, in Ireland.</p>
+
+<p>11. <span class="smcap">Granophyre.</span>&mdash;This term, according to Geikie, embraces
+the greater portion of the acid volcanic rocks of the
+Inner Hebrides. They are closely allied to the quartz-porphyries,
+and vary in texture from a fine felsitic or crystalline-granular
+quartz-porphyry, in the ground-mass of which
+porphyritic turbid felspar and quartz may generally be detected,
+to a granitoid rock of medium grain, in which the
+component dull felspar and clear quartz can be readily distinguished
+by the naked eye. Throughout all the varieties of
+texture there is a strong tendency to the development of
+minute irregularly-shaped cavities, inside of which quartz or
+felspar has crystallised out&mdash;a feature characteristic of the
+granites of Arran and of the Mourne Mountains.</p>
+
+<p>12. <span class="smcap">Granite.</span>&mdash;A true granite consists of a crystalline-granular
+rock consisting of quartz, felspar (orthoclase), and
+mica; the quartz is the paste or ground-mass in which the
+felspar and mica crystals are enclosed. This is the essential
+distinction between a granite and a quartz-porphyry or a granophyre.
+Owing to the presence of highly-heated steam under
+pressure in the body of the mass when in a molten condition,
+the quartz has been the last of the minerals to crystallise out,
+and hence does not itself occur with the crystalline form.</p>
+
+<p>True granite is not a volcanic rock, and its representatives
+amongst volcanic ejecta are to be found in the granophyres,
+<span class="pagenum"><a name="Page_265" id="Page_265">[Pg 265]</a></span>quartz-porphyries, felsites, trachytes, and rhyolites so abundant
+in most volcanic countries, and to one or other of these the
+so-called granites of the Mourne Mountains, of Arran Island,
+and of Skye are to be referred. Granite is a rock which has
+been intruded in a molten condition amongst the deep-seated
+parts of the crust, and has consolidated under great pressure in
+presence of aqueous vapour and with extreme slowness, resulting
+in the formation of a rock which is largely crystalline-granular.
+Its presence at the surface is due to denudation of the masses
+by which it was originally overspread.</p>
+
+<div class="figcenter">
+<a name="PLATE_1">
+  <span class="center"><span class="smcap">Plate I.</span></span><br />
+  <img src="images/plate1.jpg" alt="Plate I" />
+</a>
+</div>
+
+<h2>EXPLANATION OF PLATE I.</h2>
+
+<p class="center">MAGNIFIED SECTIONS OF VESUVIAN MINERALS.</p>
+
+<blockquote><p>Fig. 1. Section of leucite crystal from the lava of 1868, with fluid
+cavities. Mag., 350 diams.</p>
+
+<p>" 2, 3, 4, and 5. Sections of nepheline crystals from the lava of
+1767, 1834, and 1854.</p>
+
+<p>" 6. Section of sodalite crystal from the lava of 1794, with belonites
+and crystals of magnetite enclosed.</p>
+
+<p>" 7, 8, 9. Crystals of leucite with microliths and cavities darkened
+by magnetite dust; also, containing crystals of magnetite.</p>
+
+<p>" 10. Group of leucite crystals of irregular form from the lava of
+1855, congregated around a nucleus of crystals of plagioclase
+and magnetite.</p></blockquote>
+
+<div class="figcenter">
+<a name="PLATE_2">
+  <span class="center"><span class="smcap">Plate II.</span></span><br />
+  <img src="images/plate2.jpg" alt="Plate II" />
+</a>
+</div>
+
+<h2>EXPLANATION OF PLATE II.</h2>
+
+<p class="center">MAGNIFIED SECTIONS OF VESUVIAN MINERALS.</p>
+
+<blockquote><p>Fig. 1. Section of augite crystal from the lava of 1794, with numerous
+gas cells and delicately banded walls. The interior contains
+two long prisms, probably of apatite.</p>
+
+<p>" 2. Crystal of augite with banded walls, and indented by leucite
+crystals, from the lava of 1794. Mag., 40 diams.</p>
+
+<p>" 3, 4, 5. Sections of augite crystals from the lavas of 1794 and
+1820.</p>
+
+<p>" 6. Group of augite crystals from the lava of 1835.</p>
+
+<p>" 7. Ditto from the lava of 1822, with encluded mica-flake (<i>a</i>) and
+portion of the glass paste, or ground-mass, of the rock (<i>b</i>),
+containing microliths and grains of magnetite.</p>
+
+<p><span class="pagenum"><a name="Page_266" id="Page_266">[Pg 266]</a></span></p><p>Fig. 8. Two crystals of olivine from the lava of 1855; they are intersected
+on one side by the plane of the thin section, and are
+remarkable for showing lines of gas cells, and bands of growth
+sometimes cellular. Mag., 40 diams.</p>
+
+<p>" 9. Section of rock-crystal (quartz), with double terminal pyramids,
+from the lava of 1850.</p>
+
+<p>" 10. Twin crystal of sanidine from the lava of 1858. Mag., 40
+diams.</p>
+
+<p>" 11, 12, 13. Sections of plagioclase crystals (probably labradorite)
+from the lava of 1855. Mag., 100 diams.</p>
+
+<p>" 14. Section of olivine crystal from the lava of 1631&mdash;imperfectly
+formed. Mag., 30 diams.</p>
+
+<p>" 15. Section of mica-flake from the lava of 1822. Mag., 30 diams.</p></blockquote>
+
+<div class="figcenter">
+<a name="PLATE_3">
+  <span class="center"><span class="smcap">Plate III.</span></span><br />
+  <img src="images/plate3.jpg" alt="Plate III" />
+</a>
+</div>
+
+<h2>EXPLANATION OF PLATE III.</h2>
+
+<p class="center">MAGNIFIED SECTIONS OF VOLCANIC ROCKS.</p>
+
+<blockquote><p>1. Diorite dyke, traversing Assynt limestone, North Highlands.</p>
+
+<p>2. Basalt from upper beds, near Giant's Causeway, County Antrim.</p>
+
+<p>3. Hornblende-hypersthene-augite Andesite, from Pichupichu, Andes.</p>
+
+<p>4. Augite-Andesite from Pichupichu, Andes.</p>
+
+<p>5. Olivine dolerite, with hornblende and biotite, Madagascar.</p>
+
+<p>6. Leucite basalt, with mellilite, Capo di Bove, Italy.</p></blockquote>
+
+<div class="figcenter">
+<a name="PLATE_4">
+  <span class="center"><span class="smcap">Plate IV.</span></span><br />
+  <img src="images/plate4.jpg" alt="Plate IV" />
+</a>
+</div>
+
+<h2>EXPLANATION OF PLATE IV.</h2>
+
+<p class="center">MAGNIFIED SECTIONS OF VOLCANIC ROCKS.</p>
+
+<blockquote><p>1. Vesuvian lava, glass paste with numerous crystals of leucite; others
+of augite and nepheline porphyritically developed; also small
+grains of magnetite.</p>
+
+<p>2. Vesuvian lava, glass paste with numerous crystals of leucite; others
+of olivine, hornblende, and sanidine, porphyritically developed;
+small grains of magnetite.</p>
+
+<p>3. Trachyte from Hungary; felsitic paste with crystals of hornblende
+and sanidine, and a little magnetite.</p>
+
+<p>4. Gabbro, from Carlingford Hill, Ireland, consisting of anorthite,
+augite, a little olivine, and magnetite.</p>
+
+<p>5. Dolerite, from old volcanic neck, Scalot Hill, near Lame, consisting
+of labradorite, augite, olivine, and magnetite.</p>
+
+<p>6. Dolerite, Ballintoy, County Antrim, showing ophetic structure,
+consisting of augite, labradorite, and magnetite.</p></blockquote>
+
+<div class="footnote"><p><a name="Footnote_1_205" id="Footnote_1_205"></a><a href="#FNanchor_1_205"><span class="label">[1]</span></a> Mr. S. Allport has discovered this in the rock called the "Wolf
+Rock" off the coast of Cornwall. The most important work on basalt
+is that by F. Zirkel, <i>Unters. über mikros. Zusammensetzung und Structur
+der Basaltgesteine</i>. Bonn (1870).</p></div>
+
+<div class="footnote"><p><a name="Footnote_2_206" id="Footnote_2_206"></a><a href="#FNanchor_2_206"><span class="label">[2]</span></a> Zirkel, <i>Die mikroskopische Beschaffenheit der Mineralien und Gesteine</i>,
+p. 153. Leipsig (1873).</p></div>
+
+<div class="footnote"><p><a name="Footnote_3_207" id="Footnote_3_207"></a><a href="#FNanchor_3_207"><span class="label">[3]</span></a> Zirkel, <i>Petrog.</i>, i. 578; B. von Cotta, p. 178 (Eng. Trans.).</p></div>
+<p><span class="pagenum"><a name="Page_267" id="Page_267">[Pg 267]</a></span></p>
+
+
+<hr class="major" />
+<h1>INDEX.</h1>
+<p><span class="pagenum"><a name="Page_268" id="Page_268">[Pg 268]</a></span></p>
+
+
+<hr class="major" />
+<h2><a name="INDEX" id="INDEX"></a>INDEX.</h2>
+
+
+<p>
+Abyssinian table-lands, <a href="#Page_190">190</a> <i>et seq.</i><br />
+<br />
+Albano, Lake, <a href="#Page_89">89</a><br />
+<br />
+America, volcanic regions of North, <a href="#Page_136">136</a> <i>et seq.</i>;<br />
+<span style="margin-left: 1em;">of Western, <a href="#Page_144">144</a></span><br />
+<br />
+Andes, <a href="#Page_18">18</a>, <a href="#Page_27">27</a>, <a href="#Page_227">227</a>, <a href="#Page_254">254</a><br />
+<br />
+Andesite, <a href="#Page_263">263</a><br />
+<br />
+Antrim, <a href="#Page_154">154</a> <i>et seq.</i><br />
+<br />
+Arabia, dormant volcanoes of, <a href="#Page_126">126</a>-<a href="#Page_135">135</a><br />
+<br />
+Arabian desert, <a href="#Page_134">134</a><br />
+<br />
+Archibald, C. D., <a href="#Page_213">213</a><br />
+<br />
+Arizona, volcanoes of, <a href="#Page_137">137</a><br />
+<br />
+Argyll, Duke of, <a href="#Page_173">173</a><br />
+<br />
+Ascension, <a href="#Page_36">36</a><br />
+<br />
+Ashangi, volcanic series of, <a href="#Page_192">192</a><br />
+<br />
+Atmospheric effects of Krakatoa eruption, <a href="#Page_213">213</a>-<a href="#Page_214">214</a><br />
+<br />
+Auckland district, volcanoes of, <a href="#Page_147">147</a><br />
+<br />
+Auvergne, volcanic regions of, <a href="#Page_14">14</a>, <a href="#Page_16">16</a>, <a href="#Page_92">92</a> <i>et seq.</i><br />
+<br />
+Azores, <a href="#Page_32">32</a><br />
+<br />
+<br />
+Ball, Sir R. S., <a href="#Page_242">242</a>, <a href="#Page_244">244</a><br />
+<br />
+Basalt, <a href="#Page_260">260</a><br />
+<br />
+Blanford, W. T., <a href="#Page_188">188</a>, <a href="#Page_189">189</a><br />
+<br />
+Bonneville, Lake, <a href="#Page_141">141</a>-<a href="#Page_142">142</a><br />
+<br />
+British Isles,<br />
+<span style="margin-left: 1em;">Tertiary volcanic districts of, <a href="#Page_154">154</a> <i>et seq.</i>, <a href="#Page_227">227</a>;</span><br />
+<span style="margin-left: 1em;">pre-Tertiary volcanic districts of, <a href="#Page_196">196</a> <i>et seq.</i></span><br />
+<br />
+Buch, L. von, <a href="#Page_6">6</a>, <a href="#Page_11">11</a>, <a href="#Page_24">24</a><br />
+<br />
+<br />
+California, volcanoes of, <a href="#Page_140">140</a><br />
+<br />
+Callirrhoë, springs of, <a href="#Page_133">133</a><br />
+<br />
+Cañon, the Grand, <a href="#Page_138">138</a><br />
+<br />
+Cantal, volcanoes of the, <a href="#Page_99">99</a>-<a href="#Page_101">101</a><br />
+<br />
+Cape Colony, Basalts of, <a href="#Page_194">194</a><br />
+<br />
+Charleston earthquake, <a href="#Page_218">218</a>, <a href="#Page_222">222</a>, <a href="#Page_224">224</a><br />
+<br />
+Chambers, G. F., <a href="#Page_246">246</a><br />
+<br />
+Charnwood Forest, <a href="#Page_198">198</a><br />
+<br />
+Chimborazo, <a href="#Page_18">18</a><br />
+<br />
+Clermont, vale of, <a href="#Page_96">96</a>-<a href="#Page_97">97</a><br />
+<br />
+Clinkstone, <a href="#Page_263">263</a><br />
+<br />
+Cordilleras of Quito, <a href="#Page_25">25</a><br />
+<br />
+Cotopaxi, <a href="#Page_16">16</a>-<a href="#Page_18">18</a>, <a href="#Page_24">24</a>, <a href="#Page_26">26</a><br />
+<br />
+Crater-cones, Lava, <a href="#Page_19">19</a><br />
+<br />
+Crateriform cones, <a href="#Page_13">13</a><br />
+<br />
+Craterless domes, <a href="#Page_15">15</a><br />
+<br />
+<br />
+Dana, Prof. J. D., <a href="#Page_19">19</a>, <a href="#Page_39">39</a>, <a href="#Page_249">249</a><br />
+<br />
+Darwin, <a href="#Page_28">28</a>, <a href="#Page_30">30</a><br />
+<br />
+Darwin, Prof. G. H., <a href="#Page_9">9</a>, <a href="#Page_231">231</a><br />
+<br />
+Daubeny, <a href="#Page_7">7</a>, <a href="#Page_61">61</a>, <a href="#Page_69">69</a><br />
+<br />
+Davison, C., <a href="#Page_9">9</a>, <a href="#Page_231">231</a><br />
+<br />
+Davy, Sir H., <a href="#Page_11">11</a><br />
+<br />
+Deccan trap-series, <a href="#Page_187">187</a> <i>et seq.</i><br />
+<br />
+Demavend, Mount, <a href="#Page_24">24</a><br />
+<br />
+Diabase, <a href="#Page_262">262</a><br />
+<br />
+Diorite, <a href="#Page_261">261</a><br />
+<br />
+Dolerite, <a href="#Page_261">261</a><br />
+<br />
+Domite, <a href="#Page_263">263</a><br />
+<br />
+Dore, volcanoes of Mont, <a href="#Page_100">100</a>-<a href="#Page_101">101</a><br />
+<br />
+Doughty, C. M., <a href="#Page_127">127</a><br />
+<br />
+Durocher, <a href="#Page_232">232</a><br />
+<br />
+Dutton, Capt. C. E., <a href="#Page_9">9</a>, <a href="#Page_220">220</a>, <a href="#Page_222">222</a><br />
+<br />
+Dykes in Ireland, <a href="#Page_169">169</a>-<a href="#Page_170">170</a><br />
+<br />
+<br />
+Earthquakes, <a href="#Page_217">217</a> <i>et seq.</i><br />
+<br />
+Errigal, <a href="#Page_10">10</a><br />
+<br />
+<span class="pagenum"><a name="Page_269" id="Page_269">[Pg 269]</a></span>Etna, <a href="#Page_14">14</a>, <a href="#Page_61">61</a> <i>et seq.</i>, <a href="#Page_229">229</a><br />
+<br />
+<br />
+Fingal's Cave, <a href="#Page_185">185</a><br />
+<br />
+Forbes, D., <a href="#Page_27">27</a><br />
+<br />
+France, extinct volcanoes of, <a href="#Page_92">92</a> <i>et seq.</i><br />
+<br />
+<br />
+Gabbro, <a href="#Page_261">261</a><br />
+<br />
+Gardner, J. S., <a href="#Page_156">156</a><br />
+<br />
+Geikie, Sir A., <a href="#Page_8">8</a>, <a href="#Page_29">29</a>, <a href="#Page_143">143</a>, <a href="#Page_156">156</a>, <a href="#Page_160">160</a>, <a href="#Page_169">169</a>, <a href="#Page_172">172</a>, <a href="#Page_176">176</a>, <a href="#Page_177">177</a>, <a href="#Page_196">196</a><br />
+<br />
+Giant's Causeway, <a href="#Page_165">165</a>-<a href="#Page_166">166</a><br />
+<br />
+Granite, <a href="#Page_264">264</a><br />
+<br />
+Granophyre, <a href="#Page_264">264</a>; of Mull, <a href="#Page_174">174</a><br />
+<br />
+Green, Prof. A. H., <a href="#Page_194">194</a><br />
+<br />
+<br />
+Hatch, Dr., <a href="#Page_260">260</a><br />
+<br />
+Haughton, Prof., <a href="#Page_68">68</a><br />
+<br />
+Haurân, volcanoes of the, <a href="#Page_22">22</a>, <a href="#Page_129">129</a><br />
+<br />
+Haute Loire, volcanic districts of, <a href="#Page_101">101</a>-<a href="#Page_105">105</a><br />
+<br />
+Hawaii, volcanoes of, <a href="#Page_39">39</a>, <a href="#Page_249">249</a>, <a href="#Page_251">251</a><br />
+<br />
+Hecla, <a href="#Page_32">32</a><br />
+<br />
+Herschel, Sir J., <a href="#Page_244">244</a><br />
+<br />
+Hibbert, Dr. S., <a href="#Page_6">6</a>, <a href="#Page_114">114</a>, <a href="#Page_124">124</a><br />
+<br />
+Hochstetter, F. von, <a href="#Page_147">147</a><br />
+<br />
+Hopkins, <a href="#Page_171">171</a>, <a href="#Page_217">217</a><br />
+<br />
+Hull, Dr. E. G., <a href="#Page_110">110</a><br />
+<br />
+Humboldt, A. von, <a href="#Page_20">20</a>, <a href="#Page_25">25</a><br />
+<br />
+Hutton, James, <a href="#Page_5">5</a><br />
+<br />
+<br />
+Iceland, volcanoes of, <a href="#Page_30">30</a>-<a href="#Page_32">32</a><br />
+<br />
+Ireland, volcanic Tertiary rocks of, <a href="#Page_154">154</a> <i>et seq.</i><br />
+<br />
+<br />
+Jaulân, <a href="#Page_129">129</a><br />
+<br />
+Johnston-Lavis, <a href="#Page_52">52</a><br />
+<br />
+Jordan valley, <a href="#Page_126">126</a> <i>et seq.</i>, <a href="#Page_226">226</a><br />
+<br />
+Jorullo, <a href="#Page_24">24</a><br />
+<br />
+Judd, Prof., <a href="#Page_8">8</a>, <a href="#Page_68">68</a>, <a href="#Page_69">69</a>, <a href="#Page_71">71</a>, <a href="#Page_172">172</a>, <a href="#Page_178">178</a>, <a href="#Page_208">208</a><br />
+<br />
+<br />
+Krakatoa, eruption of, <a href="#Page_206">206</a> <i>et seq.</i><br />
+<br />
+Kurile Islands, volcanoes of, <a href="#Page_28">28</a><br />
+<br />
+<br />
+Laacher See, <a href="#Page_121">121</a>-<a href="#Page_123">123</a><br />
+<br />
+Lampophyre, <a href="#Page_262">262</a><br />
+<br />
+Lancerote, <a href="#Page_34">34</a><br />
+<br />
+Lasaulx, Prof. von, <a href="#Page_68">68</a><br />
+<br />
+Lavas, relative density of, <a href="#Page_232">232</a>-<a href="#Page_234">234</a><br />
+<br />
+Lima in 1746, earthquake of, <a href="#Page_222">222</a><br />
+<br />
+Lipari Islands, volcanoes of, <a href="#Page_69">69</a> <i>et seq.</i><br />
+<br />
+Lisbon, earthquake of, <a href="#Page_221">221</a><br />
+<br />
+Lister, J. J., <a href="#Page_38">38</a><br />
+<br />
+Lunar volcanoes, <a href="#Page_236">236</a> <i>et seq.</i><br />
+<br />
+Lyell, Sir C., <a href="#Page_30">30</a>, <a href="#Page_62">62</a>, <a href="#Page_78">78</a>, <a href="#Page_217">217</a><br />
+<br />
+<br />
+Mackowen, Col., <a href="#Page_74">74</a><br />
+<br />
+Magdala, volcanic series of, <a href="#Page_192">192</a>-<a href="#Page_193">193</a><br />
+<br />
+Mallet, R., <a href="#Page_9">9</a>, <a href="#Page_217">217</a><br />
+<br />
+Mauna Loa, <a href="#Page_19">19</a>, <a href="#Page_39">39</a>, <a href="#Page_249">249</a><br />
+<br />
+Mica-trap, <a href="#Page_262">262</a><br />
+<br />
+Milne, Prof., <a href="#Page_28">28</a>, <a href="#Page_218">218</a>, <a href="#Page_253">253</a><br />
+<br />
+Moab, volcanic regions of, <a href="#Page_132">132</a><br />
+<br />
+Moon, volcanoes of, <a href="#Page_236">236</a> <i>et seq.</i><br />
+<br />
+Monte Nuovo, <a href="#Page_85">85</a><br />
+<br />
+Mull, <a href="#Page_172">172</a> <i>et seq.</i><br />
+<br />
+<br />
+Neapolitan group of volcanoes, <a href="#Page_28">28</a><br />
+<br />
+New Zealand, volcanoes of, <a href="#Page_146">146</a><br />
+<br />
+<br />
+Obsidian, <a href="#Page_264">264</a><br />
+<br />
+Ocean waves of seismic origin, <a href="#Page_208">208</a>, <a href="#Page_220">220</a><br />
+<br />
+O'Reilly, Prof., <a href="#Page_9">9</a>, <a href="#Page_219">219</a><br />
+<br />
+Orizaba, <a href="#Page_21">21</a><br />
+<br />
+Ovid, <a href="#Page_3">3</a><br />
+<br />
+<br />
+Pacific, volcanic islands of, <a href="#Page_37">37</a><br />
+<br />
+Palestine, dormant volcanoes of, <a href="#Page_126">126</a>-<a href="#Page_135">135</a><br />
+<br />
+Palmieri, Prof., <a href="#Page_55">55</a><br />
+<br />
+Pantelleria, <a href="#Page_74">74</a><br />
+<br />
+Phlegræan fields, <a href="#Page_85">85</a><br />
+<br />
+Phonolite, <a href="#Page_263">263</a><br />
+<br />
+Pitchstone, <a href="#Page_264">264</a><br />
+<br />
+Pliny, <a href="#Page_2">2</a>, <a href="#Page_4">4</a><br />
+<br />
+Porphyrite, <a href="#Page_262">262</a><br />
+<br />
+Powell, Major, <a href="#Page_138">138</a><br />
+<br />
+Pre-Tertiary volcanic rocks, <a href="#Page_187">187</a> <i>et seq.</i>;<br />
+<span style="margin-left: 1em;">of British Isles, <a href="#Page_196">196</a> <i>et seq.</i></span><br />
+<br />
+Puy de Dôme, <a href="#Page_105">105</a>-<a href="#Page_110">110</a><br />
+<br />
+Pythagoreans on volcanoes, <a href="#Page_2">2</a>-<a href="#Page_3">3</a><br />
+<br />
+<br />
+Quito, Cordilleras of, <a href="#Page_25">25</a><br />
+<br />
+<br />
+Rangitoto, <a href="#Page_19">19</a>, <a href="#Page_149">149</a><br />
+<br />
+Reyer, Dr. E., <a href="#Page_17">17</a><br />
+<br />
+Rhine valley, volcanoes of, <a href="#Page_113">113</a> <i>et seq.</i><br />
+<br />
+<span class="pagenum"><a name="Page_270" id="Page_270">[Pg 270]</a></span>Rhyolite, <a href="#Page_263">263</a><br />
+<br />
+Riviera in 1887, earthquake of, <a href="#Page_219">219</a><br />
+<br />
+Rocca Monfina, <a href="#Page_80">80</a><br />
+<br />
+Roderberg, <a href="#Page_119">119</a>, <a href="#Page_120">120</a><br />
+<br />
+Rome, <a href="#Page_88">88</a>-<a href="#Page_89">89</a><br />
+<br />
+Rosenbusch, H., <a href="#Page_260">260</a><br />
+<br />
+Roto Mahana, <a href="#Page_151">151</a><br />
+<br />
+Ruapahu, <a href="#Page_151">151</a><br />
+<br />
+Russell, Hon. Rollo, <a href="#Page_213">213</a><br />
+<br />
+Rutley, F., <a href="#Page_260">260</a><br />
+<br />
+<br />
+St. Helena, <a href="#Page_37">37</a><br />
+<br />
+San Francisco, Mount, <a href="#Page_138">138</a><br />
+<br />
+Santorin, <a href="#Page_76">76</a>-<a href="#Page_83">83</a><br />
+<br />
+Schehallion, <a href="#Page_10">10</a><br />
+<br />
+Schumacher, <a href="#Page_127">127</a><br />
+<br />
+Scotland, volcanic districts of, <a href="#Page_172">172</a> <i>et seq.</i><br />
+<br />
+Scrope, Poulett, <a href="#Page_5">5</a>, <a href="#Page_73">73</a>, <a href="#Page_93">93</a>, <a href="#Page_98">98</a><br />
+<br />
+Scuir of Eigg, <a href="#Page_180">180</a>-<a href="#Page_184">184</a><br />
+<br />
+Seismic phenomena, special, <a href="#Page_201">201</a> <i>et seq.</i>, <a href="#Page_217">217</a> <i>et seq.</i><br />
+<br />
+Shasta, Mount, <a href="#Page_140">140</a><br />
+<br />
+Siebengebirge, <a href="#Page_116">116</a>-<a href="#Page_120">120</a><br />
+<br />
+Skye, <a href="#Page_177">177</a>-<a href="#Page_179">179</a><br />
+<br />
+Sleamish, <a href="#Page_168">168</a><br />
+<br />
+Smyth, Piazzi, <a href="#Page_33">33</a><br />
+<br />
+Snake River, volcanoes of, <a href="#Page_142">142</a><br />
+<br />
+Staffa, <a href="#Page_185">185</a>-<a href="#Page_186">186</a><br />
+<br />
+Strabo on volcanoes, <a href="#Page_3">3</a><br />
+<br />
+Stromboli, <a href="#Page_71">71</a>-<a href="#Page_73">73</a><br />
+<br />
+Sumatra, volcanic action in, <a href="#Page_226">226</a><br />
+<br />
+Syenite, <a href="#Page_262">262</a><br />
+<br />
+Symes, R. G., <a href="#Page_167">167</a><br />
+<br />
+Syria, earthquakes in, <a href="#Page_219">219</a><br />
+<br />
+<br />
+Taupo Lake, <a href="#Page_150">150</a><br />
+<br />
+Taylor, Mount, <a href="#Page_138">138</a><br />
+<br />
+Tell el Ahmâr, <a href="#Page_131">131</a><br />
+<br />
+Tell el Akkasheh, <a href="#Page_131">131</a><br />
+<br />
+Tell el Farras, <a href="#Page_131">131</a><br />
+<br />
+Tell Abû en Nedâ, <a href="#Page_130">130</a><br />
+<br />
+Tell Abû Nedîr, <a href="#Page_129">129</a><br />
+<br />
+Templepatrick, quarry at, <a href="#Page_160">160</a><br />
+<br />
+Teneriffe, <a href="#Page_33">33</a><br />
+<br />
+Tertiary period, volcanic activity of, <a href="#Page_255">255</a><br />
+<br />
+Thucydides, <a href="#Page_2">2</a><br />
+<br />
+Tonga Islands, volcanoes of, <a href="#Page_38">38</a><br />
+<br />
+Tongariro, <a href="#Page_151">151</a><br />
+<br />
+Trachyte, <a href="#Page_263">263</a><br />
+<br />
+Trass of Brühl Valley, <a href="#Page_123">123</a>-<a href="#Page_125">125</a><br />
+<br />
+Tristan da Cunha, <a href="#Page_37">37</a><br />
+<br />
+Tristram, Canon, <a href="#Page_127">127</a>, <a href="#Page_131">131</a><br />
+<br />
+<br />
+Utah, volcanoes of, <a href="#Page_137">137</a><br />
+<br />
+<br />
+Verbeek, R. D. M., <a href="#Page_202">202</a><br />
+<br />
+Vesuvius, <a href="#Page_4">4</a>, <a href="#Page_14">14</a>, <a href="#Page_41">41</a>-<a href="#Page_60">60</a>, <a href="#Page_67">67</a>, <a href="#Page_229">229</a><br />
+<br />
+Volcanoes,<br />
+<span style="margin-left: 1em;">historic notices of, <a href="#Page_1">1</a>-<a href="#Page_5">5</a>;</span><br />
+<span style="margin-left: 1em;">form, structure, and composition of, <a href="#Page_10">10</a>-<a href="#Page_19">19</a>;</span><br />
+<span style="margin-left: 1em;">lines and groups of active, <a href="#Page_20">20</a>-<a href="#Page_29">29</a>;</span><br />
+<span style="margin-left: 1em;">of mid-ocean, <a href="#Page_30">30</a>-<a href="#Page_40">40</a>;</span><br />
+<span style="margin-left: 1em;">extinct or dormant, <a href="#Page_84">84</a> <i>et seq.</i>;</span><br />
+<span style="margin-left: 1em;">special volcanic and seismic phenomena, <a href="#Page_201">201</a> <i>et seq.</i>;</span><br />
+<span style="margin-left: 1em;">the ultimate cause of volcanic action, <a href="#Page_225">225</a> <i>et seq.</i>;</span><br />
+<span style="margin-left: 1em;">whether we are living in an epoch of special volcanic activity, <a href="#Page_253">253</a>-<a href="#Page_256">256</a>;</span><br />
+<span style="margin-left: 1em;">brief account of volcanic rocks, <a href="#Page_259">259</a>-<a href="#Page_265">265</a></span><br />
+<br />
+Vulcanists, <a href="#Page_5">5</a><br />
+<br />
+Vulcano, <a href="#Page_69">69</a>, <a href="#Page_71">71</a><br />
+<br />
+<br />
+Wallace, A. R., <a href="#Page_81">81</a><br />
+<br />
+Waltershausen, W. S. von, <a href="#Page_7">7</a>, <a href="#Page_61">61</a><br />
+<br />
+Wellington, Mount, <a href="#Page_149">149</a><br />
+<br />
+Wharton, Capt., <a href="#Page_212">212</a><br />
+<br />
+Whymper, E., <a href="#Page_18">18</a><br />
+<br />
+<br />
+Yarmûk, valley of the, <a href="#Page_129">129</a>, <a href="#Page_131">131</a><br />
+<br />
+Yellowstone Park, <a href="#Page_145">145</a><br />
+<br />
+<br />
+Zirkel, F., <a href="#Page_260">260</a><br />
+<br />
+Zöllner, <a href="#Page_240">240</a><br />
+</p>
+
+
+<p class="center">THE WALTER SCOTT PRESS, NEWCASTLE-ON-TYNE.</p>
+
+
+
+<hr class="major" />
+<h2><a name="The_Contemporary_Science_Series" id="The_Contemporary_Science_Series"></a>The Contemporary Science Series.</h2>
+
+<p class="center">EDITED BY HAVELOCK ELLIS.</p>
+
+<hr class="tb" />
+
+<p class="center">Crown 8vo, Cloth, 3s. 6d. per vol.; Half Morocco, 6s. 6d.</p>
+
+<blockquote><p>I. THE EVOLUTION OF SEX. By Professor <span class="smcap">Patrick Geddes</span> and
+<span class="smcap">J. Arthur Thomson</span>. With 90 Illustrations. Second Edition.</p></blockquote>
+
+<p>"The authors have brought to the task&mdash;as indeed their names guarantee&mdash;a
+wealth of knowledge, a lucid and attractive method of treatment, and a
+rich vein of picturesque language."&mdash;<i>Nature.</i></p>
+
+<blockquote><p>II. ELECTRICITY IN MODERN LIFE. By <span class="smcap">G. W. de Tunzelmann</span>.
+With 88 Illustrations.</p></blockquote>
+
+<p>"A clearly-written and connected sketch of what is known about electricity
+and magnetism, the more prominent modern applications, and the principles
+on which they are based."&mdash;<i>Saturday Review.</i></p>
+
+<blockquote><p>III. THE ORIGIN OF THE ARYANS. By Dr. <span class="smcap">Isaac Taylor</span>. Illustrated.
+Second Edition.</p></blockquote>
+
+<p>"Canon Taylor is probably the most encyclopædic all-round scholar now
+living. His new volume on the Origin of the Aryans is a first-rate example of
+the excellent account to which he can turn his exceptionally wide and varied
+information.... Masterly and exhaustive."&mdash;<i>Pall Mall Gazette.</i></p>
+
+<blockquote><p>IV. PHYSIOGNOMY AND EXPRESSION. By <span class="smcap">P. Mantegazza</span>.
+Illustrated.</p></blockquote>
+
+<p>"Professor Mantegazza is a writer full of life and spirit, and the natural
+attractiveness of his subject is not destroyed by his scientific handling of it."&mdash;<i>Literary
+World</i> (Boston).</p>
+
+<blockquote><p>V. EVOLUTION AND DISEASE. By <span class="smcap">J. B. Sutton</span>, F.R.C.S. With
+135 Illustrations.</p></blockquote>
+
+<p>"The work is of special value to professional men, yet educated persons
+generally will find much in it which it is both interesting and important to
+know."&mdash;<i>The Scottish Weekly.</i></p>
+
+<blockquote><p>VI. THE VILLAGE COMMUNITY. By <span class="smcap">G. L. Gomme</span>. Illustrated.</p></blockquote>
+
+<p>"His book will probably remain for some time the best work of reference
+for facts bearing on those traces of the village community which have not
+been effaced by conquest, encroachment, and the heavy hand of Roman law."&mdash;<i>Scottish
+Leader.</i></p>
+
+<blockquote><p>VII. THE CRIMINAL. By <span class="smcap">Havelock Ellis</span>. Illustrated.</p></blockquote>
+
+<p>"An ably written, an instructive, and a most entertaining book."&mdash;<i>Law
+Quarterly Review.</i></p>
+
+<hr class="tb" />
+
+<p class="center">London: <span class="smcap">Walter Scott, Limited</span>, 24 Warwick Lane.</p>
+<hr class="major" />
+
+<h2>The Contemporary Science Series&mdash;continued.</h2>
+
+<blockquote><p>VIII. SANITY AND INSANITY. By Dr. <span class="smcap">Charles Mercier</span>. Illustrated.</p></blockquote>
+
+<p>"Taken as a whole, it is the brightest book on the physical side of mental
+science published in our time."&mdash;<i>Pall Mall Gazette.</i></p>
+
+<blockquote><p>IX. HYPNOTISM. By Dr. <span class="smcap">Albert Moll</span>. Second Edition.</p></blockquote>
+
+<p>"Marks a step of some importance in the study of some difficult physiological
+and psychological problems which have not yet received much attention
+in the scientific world of England."&mdash;<i>Nature.</i></p>
+
+<blockquote><p>X. MANUAL TRAINING. By Dr. <span class="smcap">C. M. Woodward</span>, Director of the
+Manual Training School, St. Louis. Illustrated.</p></blockquote>
+
+<p>"There is no greater authority on the subject than Professor Woodward."&mdash;<i>Manchester
+Guardian.</i></p>
+
+<blockquote><p>XI. THE SCIENCE OF FAIRY TALES. By <span class="smcap">E. Sidney Hartland</span>.</p></blockquote>
+
+<p>"Mr. Hartland's book will win the sympathy of all earnest students, both
+by the knowledge it displays, and by a thorough love and appreciation of his
+subject, which is evident throughout."&mdash;<i>Spectator.</i></p>
+
+<blockquote><p>XII. PRIMITIVE FOLK. By <span class="smcap">Elie Reclus</span>.</p></blockquote>
+
+<p>"For an introduction to the study of the questions of property, marriage,
+government, religion,&mdash;in a word, to the evolution of society,&mdash;this little
+volume will be found most convenient."&mdash;<i>Scottish Leader.</i></p>
+
+<blockquote><p>XIII. THE EVOLUTION OF MARRIAGE. By Professor <span class="smcap">Letourneau</span>.</p></blockquote>
+
+<p>"Among the distinguished French students of sociology, Professor Letourneau
+has long stood in the first rank. He approaches the great study of man
+free from bias and shy of generalisations. To collect, scrutinise, and appraise
+facts is his chief business."&mdash;<i>Science.</i></p>
+
+<blockquote><p>XIV. BACTERIA AND THEIR PRODUCTS. By Dr. <span class="smcap">G. Sims Woodhead</span>.
+Illustrated.</p></blockquote>
+
+<p>"An excellent summary of the present state of knowledge of the subject."&mdash;<i>Lancet.</i></p>
+
+<blockquote><p>XV. EDUCATION AND HEREDITY. By <span class="smcap">J. M. Guyau</span>.</p></blockquote>
+
+<p>"It is a sign of the value of this book that the natural impulse on arriving
+at its last page is to turn again to the first, and try to gather up and coordinate
+some of the many admirable truths it presents."&mdash;<i>Anti-Jacobin.</i></p>
+
+<blockquote><p>XVI. THE MAN OF GENIUS. By Professor <span class="smcap">Lombroso</span>. Illustrated.</p></blockquote>
+
+<p>"By far the most comprehensive and fascinating collection of facts and
+generalisations concerning genius which has yet been brought together."&mdash;<i>Journal
+of Mental Science.</i></p>
+
+<blockquote><p>XVII. THE GRAMMAR OF SCIENCE. By Professor <span class="smcap">Karl Pearson</span>.
+Illustrated.</p></blockquote>
+
+<blockquote><p>XVIII. PROPERTY: ITS ORIGIN AND DEVELOPMENT. By <span class="smcap">Ch.
+Letourneau</span>, General Secretary to the Anthropological Society, Paris,
+and Professor in the School of Anthropology, Paris.</p></blockquote>
+
+<p>An ethnological account of the beginnings of property among animals, of its
+communistic stages among primitive races, and of its later individualistic developments,
+together with a brief sketch of its probable evolution in the future.</p>
+
+<hr class="tb" />
+
+<p class="center">London: <span class="smcap">Walter Scott, Limited</span>, 24 Warwick Lane.</p>
+
+
+
+<hr class="major" />
+<h2><a name="Transcribers_Notes" id="Transcribers_Notes"></a>Transcriber's Note:</h2>
+
+
+<p>Changed what appeared to be upsilon with inverted breve to upsilon with
+perispomeni in the Greek on page 2.</p>
+
+<p>Changed 'Kilarrea' to 'Kilauea' on page 19: Mauna Loa and Kilarrea.</p>
+
+<p>Changed 'Kilanea' to 'Kilauea' on page 39: Kilanea, 4158 feet.</p>
+
+<p>Made punctuation (semi-colons) consistent in caption to figure 16.</p>
+
+<p>Changed 'Brionde' to 'Brioude' on page 94: till at Brionde it becomes.</p>
+
+<p>Changed 'occuping' to 'occupying' on page 96: occuping a hollow.</p>
+
+<p>Changed 'Rodesberg' to 'Roderberg' on page 118: old extinct volcano
+of Rodesberg.</p>
+
+<p>Changed 'Wolkenberg' to 'Wolkenburg' on page 118: and that of
+the Wolkenberg.</p>
+
+<p>Left the reference to Jeremiah, l. 25. in footnote to Part III Chapter I,
+although Jeremiah, li. 25. seems more appropriate.</p>
+
+<p>Changed 'fumarols' to 'fumaroles' on page 137: fumarols give evidence.</p>
+
+<p>Removed extra comma on page 153: of the present, epoch.</p>
+
+<p>Changed 'columnal' to 'columnar' on page 176: the columnal structure.</p>
+
+<p>Changed 'groves' to 'grooves' on page 183: the groves and scorings.</p>
+
+<p>Changed 'Angust' to 'August' on page 212: the 27th of Angust.</p>
+
+<p>Changed 'mikroskopischen' to 'mikroskopische' on page 260:
+über mikroskopischen Structur.</p>
+
+<p>Changed 'become' to 'becomes' on page 260: the rock become a leucite-basalt.</p>
+
+<p>Left inconsistent spellings of
+'Baalbec' and 'Baalbeck';
+'Harrat' and 'Harrât';
+'mètres' and 'metres';
+'pitchstone' and 'pitch-stone';
+'prehistoric' and 'pre-historic';
+'Rhône' and 'Rhone';
+'sub-aerial', 'subaërial' and 'subaerial';
+'tableland' and 'table-land'.</p>
+
+<p>Left the list numbering as is at the beginning of Chapter II of Part IV,
+even though the list begins at item c, as if it continues the list which
+began in the previous chapter.</p>
+
+<p>Footnotes were collected at the end of each chapter, and text was flowed
+to move illustrations between paragraphs.
+This has some effect on the index, since the referred-to text may have
+been moved to a different page.</p>
+
+<p>&nbsp;</p>
+<p>&nbsp;</p>
+<hr class="full" />
+<p>***END OF THE PROJECT GUTENBERG EBOOK VOLCANOES: PAST AND PRESENT***</p>
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+</html>
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