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+Project Gutenberg (https://www.gutenberg.org) public repository for
+eBook #66033 (https://www.gutenberg.org/ebooks/66033)
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-The Project Gutenberg eBook of Direct Conversion of Energy, by
-William R. Corliss
-
-This eBook is for the use of anyone anywhere in the United States and
-most other parts of the world 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
-www.gutenberg.org. If you are not located in the United States, you
-will have to check the laws of the country where you are located before
-using this eBook.
-
-Title: Direct Conversion of Energy
-
-Author: William R. Corliss
-
-Release Date: August 11, 2021 [eBook #66033]
-
-Language: English
-
-Produced by: Stephen Hutcheson and the Online Distributed Proofreading
-             Team at https://www.pgdp.net 
-
-*** START OF THE PROJECT GUTENBERG EBOOK DIRECT CONVERSION OF
-ENERGY ***
-
-
-
-
-
-                      Direct Conversion of Energy
-
-
-    [Illustration: uncaptioned]
-
-                         By William R. Corliss
-
-
-                     U.S. ATOMIC ENERGY COMMISSION
-                   Division of Technical Information
-
-
-                          _ONE OF A SERIES ON
-                        UNDERSTANDING THE ATOM_
-
-  UNITED STATES ATOMIC ENERGY COMMISSION
-  _Dr. Glenn T. Seaborg, Chairman_
-  _James T. Ramey_
-  _Dr. Gerald F. Tape_
-  _Wilfrid E. Johnson_
-
-
-Nuclear energy is playing a vital role in the life of every man, woman,
-and child in the United States today. In the years ahead it will affect
-increasingly all the peoples of the earth. It is essential that all
-Americans gain an understanding of this vital force if they are to
-discharge thoughtfully their responsibilities as citizens and if they
-are to realize fully the myriad benefits that nuclear energy offers
-them.
-
-The United States Atomic Energy Commission provides this booklet to help
-you achieve such understanding.
-
-                                                  {Edward J. Brunenkant}
-                                                    Edward J. Brunenkant
-                                                                Director
-                                       Division of Technical Information
-
-
-
-
-                                CONTENTS
-
-
-  INTRODUCTION                                                         1
-  DIRECT VERSUS DYNAMIC ENERGY CONVERSION                              3
-  LAWS GOVERNING ENERGY CONVERSION                                     8
-  THERMOELECTRICITY                                                   12
-  THERMIONIC CONVERSION                                               16
-  MAGNETOHYDRODYNAMIC CONVERSION                                      19
-  CHEMICAL BATTERIES                                                  22
-  THE FUEL CELL: A CONTINUOUSLY FUELED BATTERY                        24
-  SOLAR CELLS                                                         26
-  NUCLEAR BATTERIES                                                   28
-  ADVANCED CONCEPTS                                                   30
-  SUGGESTED REFERENCES                                                33
-  ANSWERS TO PROBLEMS                                                 34
-
-
-Library of Congress Catalog Card Number: 64-61794
-
-
-ABOUT THE AUTHOR
-
-    [Illustration: William R. Corliss]
-
-WILLIAM R. CORLISS is an atomic energy consultant and writer with 12
-years of industrial experience including service as Director of Advanced
-Programs for the Martin Company’s Nuclear Division. Mr. Corliss has B.S.
-and M.S. Degrees in Physics from Rensselaer Polytechnic Institute and
-the University of Colorado, respectively. He has taught at those two
-institutions and at the University of Wisconsin. He is the author of
-_Propulsion Systems for Space Flight_ (McGraw-Hill 1960), _Space Probes
-and Planetary Exploration_ (Van Nostrand 1965), _Mysteries of the
-Universe_ (Crowell 1967), _Scientific Satellites_ (GPO 1967), and
-coauthor of _Radioisotopic Power Generation_ (Prentice-Hall 1964), as
-well as numerous articles and papers for technical journals and
-conferences. In this series he has written _Neutron Activation
-Analysis_, _Power Reactors in Small Packages_, _SNAP—Nuclear Reactor
-Power in Space_, _Computers_, _Nuclear Propulsion for Space_, _Space
-Radiation_, and was coauthor of _Power from Radioisotopes_.
-
-
-
-
-                              INTRODUCTION
-
-
-A flashlight battery supplies electricity without moving mechanical
-parts. It converts the chemical energy of its contents _directly_ into
-electrical energy.
-
-Early direct conversion devices such as Volta’s battery, developed in
-1795, gave the scientists Ampere, Oersted, and Faraday their first
-experimental supplies of electricity. The lessons they learned about
-electrical energy and its intimate relation with magnetism spawned the
-mighty turboelectric energy converters—steam and hydroelectric
-turbines—which power modern civilization.
-
-We have improved upon Volta’s batteries and have come to rely on them as
-portable, usually small, power sources, but only recently has the
-challenge of nuclear power and space exploration focused our attention
-on new methods of direct conversion.
-
-To supply power for use in outer space and also at remote sites on
-earth, we need power sources that are reliable, light in weight, and
-capable of unattended Operation for long periods of time. Nuclear power
-plants using direct conversion techniques hold promise of surpassing
-conventional power sources in these attributes. In addition, the
-inherently silent operation of direct conversion power plants is an
-important advantage for many military applications.
-
-The Atomic Energy Commission, the Department of Defense, and the
-National Aeronautics and Space Administration collectively sponsor tens
-of millions of dollars worth of research and development in the area of
-direct conversion each year. In particular, the Atomic Energy Commission
-supports more than a dozen research and development programs in
-thermoelectric and thermionic energy conversion in industry and at the
-Los Alamos Scientific Laboratory, and other direct conversion research
-at Argonne National Laboratory and Brookhaven National Laboratory.
-Reactor and radioisotopic power plants utilizing direct conversion are
-being produced under the AEC’s SNAP[1] program. Some of these units are
-presently in use powering satellites, Arctic and Antarctic weather
-stations, and navigational buoys.
-
-Further applications are now being studied, but the cost of direct
-conversion appears too great to permit its general use for electric
-power in the near future. Direct techniques will be used first where
-their special advantages outweigh higher cost.
-
-
-
-
-                DIRECT VERSUS DYNAMIC ENERGY CONVERSION
-
-
-Dominance of Dynamic Conversion
-
-We live in a world of motion. A main task of the engineer is to find
-better and more efficient ways of transforming the energy locked in the
-sun’s rays or in fuels, such as coal and the uranium nucleus, into
-energy of motion. Almost all the world’s energy is now transformed by
-rotating or reciprocating machines. We couple the energy of exploding
-gasoline and air to our automobile’s wheels by a reciprocating engine.
-The turbogenerator at a hydroelectric plant extracts energy from falling
-water and turns it into electricity. Such rotating or reciprocating
-machines are called _dynamic_ converters.
-
-
-A New Level of Sophistication: Direct Conversion
-
-A revolution is in the making. We know now that we can force the
-heat-and-electricity-carrying electrons residing in matter to do our
-bidding without the use of shafts and pistons. This is a leading
-accomplishment of modern technology: energy transformation without
-moving parts. It is called _direct_ conversion.
-
-The thermoelements shown above the turbogenerator in Figure 1 illustrate
-the contrast between direct and dynamic conversion. The thermoelements
-convert heat into electricity directly, without any of the intervening
-machinery seen in the turbogenerator.
-
-    [Illustration: Figure 1 _Direct conversion devices, such as the
-    spokelike lead telluride thermoelectric elements inside the SNAP 3
-    radioisotope generator shown above (courtesy Martin Company),
-    convert heat into electricity without moving parts. In contrast, the
-    SNAP 2 dynamic converter shown below SNAP 3 (courtesy Thompson Ramo
-    Wooldridge, Inc.) includes a high-speed turbine, an electric
-    generator, and pumps to produce electricity from heat. (NaK is a
-    liquid mixture of sodium and potassium.)_]
-
-  DIRECT VERSUS DYNAMIC CONVERSION
-    SNAP 3 LESS THAN 5 WATTS
-      5″
-    SNAP 2 3000 WATTS
-      24″
-      ALTERNATOR ROTOR
-      ALTERNATOR STATOR
-      TURBINE ROTORS
-      NaK PUMP DIFFUSER
-      NaK PUMP ROTOR
-      MERCURY JET BOOSTER PUMP
-      MERCURY CENTRIFUGAL PUMP
-      MERCURY THRUST BEARING
-      MERCURY BEARING
-      MERCURY BEARING
-
-
-Why is Direct Conversion Desirable?
-
-There are places where energy conversion equipment must run for years
-without maintenance or breakdown. Also, there are situations where the
-ultimate in reliability is required, such as on scientific satellites
-and particularly on manned space flights. Direct conversion equipment
-seems to offer greater reliability than dynamic conversion equipment for
-these purposes.
-
-We should recognize that our belief in the superiority of direct
-conversion is based more on intuition than proof. It is true that direct
-converters will never throw piston rods or run out of lubricant. Yet,
-some satellite power failures have been caused by the degradation of
-solar cells under the bombardment of solar protons. The other types of
-direct conversion devices described in the following pages may also
-break down in ways as yet unknown. Still, today’s knowledge gives us
-hope that direct conversion will be more reliable and trustworthy than
-dynamic conversion. Direct conversion equipment is beginning to be
-adopted for small power plants, producing less than 500 watts, designed
-to operate for long periods of time in outer space and under the ocean.
-Some day, large central-station power plants may use direct conversion
-to improve their efficiencies and reliabilities.
-
-
-How is Energy Transformed?
-
-What is energy and how do we change it? Energy is a fundamental concept
-of science involving the capacity for doing work. _Kinetic_ or
-mechanical energy is the most obvious form of energy. It is defined as
-
-                                 E = ½ mv²
-  where
-    E = energy (expressed in joules)
-    m = mass of the moving object (in kilograms)
-    v = velocity (in meters per second)
-
-Energy can also be stored in chemical and nuclear substances or in the
-water behind a dam. In these quiescent states it is called _potential_
-energy. If the potential energy in a substance is abundant and easily
-released, the energy-rich substance is called a _fuel_.
-
-
-ENERGY CONVERSION MATRIX
-
-    [Illustration: Figure 2 _To find how one form of energy is converted
-    into another, start at the proper column and move down until the
-    column intersects with the desired row. The box at the intersection
-    will give typical conversion processes and examples._]
-
- FROM⇒            ELECTROMAGNETIC   CHEMICAL          NUCLEAR           THERMAL              KINETIC          ELECTRICAL          GRAVITATIONAL
-                                                                                             (MECHANICAL)
- TO⇓
-
- ELECTROMAGNETIC                    Chemiluminescence Gamma reactions   Thermal radiation    Accelerating     Electromagnetic     Unknown
-                                    (fireflies)       (Co⁵⁸ source)     (hot iron)           charge           radiation[2]
-                                                      A-bomb                                 (cyclotron)      (TV transmitter)
-                                                                                             Phosphor[2]      Electroluminescence
- CHEMICAL         Photosynthesis                      Radiation         Boiling              Dissociation by  Electrolysis        Unknown
-                  (plants)                            catalysis         (water/steam)        radiolysis       (production of
-                  Photochemistry                      (hydrazine plant) Dissociation                          aluminum)
-                  (photographic                       Ionization                                              Battery charging
-                  film)                               (cloud chamber)
- NUCLEAR          Gamma-neutron     Unknown                             Unknown              Unknown          Unknown             Unknown
-                  reactions
-                  (Be⁹+γ → Be⁸+n)
- THERMAL          Solar absorber    Combustion        Fission                                Friction         Resistance-heating  Unknown
-                  (hot sidewalk)    (fire)            (fuel element)                         (brake shoes)    (electric stove)
-                                                      Fusion
- KINETIC          Radiometer Solar  Muscle            Radioactivity     Thermal expansion                     Motors              Falling objects
-                  cell[2]                             (alpha particles) (turbines)                            Electrostriction
-                                                      A-bomb            Internal combustion                   (sonar transmitter)
-                                                                        (engines)
- ELECTRICAL       Photoelectricity  Fuel cell[2]      Nuclear           Thermoelectricity[2] MHD[2][3]                            Unknown
-                  (light meter)     Batteries[2]      battery[2]        Thermionics[2]       Conventional
-                  Radio antenna                                         Thermomagnetism[2]   generator
-                  Solar cell[2]                                         Ferroelectricity[2]
- GRAVITATIONAL    Unknown           Unknown           Unknown           Unknown              Rising objects   Unknown
-                                                                                             (rockets)
-
-
-The Energy Conversion Matrix
-
-Forms of energy are interchangeable. When gasoline is burned in an
-automobile engine, potential energy is first turned into heat. A portion
-of this heat, say 25%, is then converted into mechanical motion. The
-remainder of the heat is wasted and must be removed from the engine.
-
-A multitude of processes and devices have been found which make these
-transformations from one form of energy to another. Many of these are
-listed in the blocks in Figure 2. Asterisks refer to direct conversion
-processes, the subject matter of this booklet.
-
-To demonstrate how this diagram is to be read, let us use it to trace
-the energy transformations involved in an automobile engine. We begin
-with sunlight because all coal and oil deposits (the _fossil fuels_)
-received their initial charge of energy in the form of sunlight.
-
-The first conversion, therefore, is from electromagnetic energy to
-chemical energy via photosynthesis in living things. We trace the
-transformation by moving down the column marked Electromagnetic Energy
-until it intersects the horizontal row labeled Chemical Energy. There we
-see photosynthesis listed in the block. The next conversion is from
-chemical energy to thermal energy via combustion. We trace this by
-moving down the Chemical Energy column to the Thermal Energy row;
-combustion is listed in the appropriate block. The third and final
-conversion takes place when thermal energy is transformed into
-mechanical energy via the internal combustion engine.
-
-By the repeated use of the Energy Conversion Matrix in this way, we can
-chart any energy transformation.
-
-
-                               Problem 1
-
-  Continue the automobile example by going through the matrix twice more
-  showing how mechanical energy is converted into stored chemical energy
-  in the car’s battery.
-
-
-                               Problem 2
-
-  If 1 gram of gasoline (about a tablespoonful) yields 48,000 joules of
-  thermal energy when burned with air, how fast can it make a 1000
-  kilogram car go? Assume the car starts from rest and its engine is 25%
-  efficient.
-
-  Answers to problems are on page 34.
-
-
-
-
-                    LAWS GOVERNING ENERGY CONVERSION
-
-
-The Big Picture: Thermodynamics
-
-To the best of our knowledge, energy and mass are always conserved
-together in any transformation. This summary of experience has been made
-into a keystone of science: the Law of Conservation of Energy and Mass.
-It states that the total amount of mass and energy cannot be altered.
-This law applies to everything we do, from driving a nail to launching a
-space probe. While the conscience of the scientist insists that he
-continually recheck the truth of this law, it remains a bulwark of
-science.
-
-The Law of Conservation of Energy and Mass is also called the First Law
-of Thermodynamics. It is related to the Second Law of Thermodynamics,
-which also governs energy transformations. The Second Law says, in
-effect, that some energy will unavoidably be lost in all heat engines.
-The first two laws of thermodynamics have been paraphrased as (1) You
-can’t win; (2) You can’t even break even. Let us look at them further.
-
-
-You Can’t Win
-
-We used to think that energy and mass were conserved independently, and
-for many practical purposes we still consider them so conserved. But
-Einstein united the two with the famous equation
-
-                                  E = mc²
-
-  where
-    E = energy (in joules)
-    m = mass (in kilograms)
-    c = speed of light
-        (300,000,000 meters per second)
-
-Notice the resemblance to the kinetic energy equation shown earlier.
-Energy cannot appear without the disappearance of mass. When energy is
-locked up in a fuel, it is stored as mass. In the gasoline combustion
-problem, 1 gram of gasoline was burned with air to give 48,000 joules of
-energy. Einstein’s equation says that in this case mass disappeared in
-the amount
-
-          m = E/c² = (4.8 × 10⁴)/(9 × 10¹⁶) = 5.3 × 10⁻¹³ kilogram
-      (half a billionth of a gram)
-
-But, when an H-bomb is exploded, grams and even kilograms of mass are
-converted to energy.
-
-In direct conversion processes we do not need to worry about these mass
-changes, but at each point we must make sure that all energy is
-accounted for. For example, in outer space all energy released from
-fuels (even food) must ultimately be radiated away to empty Space.
-Otherwise the vehicle temperature will keep rising until the Spaceship
-melts.
-
-
-You Can’t Even Break Even
-
-Any engineer is annoyed by having to throw energy away. Why is energy
-ever wasted? The Second Law of Thermodynamics guides us here. Experience
-has shown that heat cannot be transformed into another form of energy
-with 100% efficiency. We can’t explain Nature’s idiosyncracies, but we
-have to live with them. So, we accept the fact that every engine that
-starts out with heat must ultimately waste some of that energy (Figure
-3).
-
-    [Illustration: Figure 3 _A typical heat engine showing heat input,
-    useful power output, and the unavoidable waste heat that must be
-    rejected to the environment. A pressure-volume diagram is shown
-    underneath for a closed gas-turbine cycle. Circled numbers
-    correspond. The energy produced is represented by the shaded area.
-    Similar diagrams can be made for all heat engines as an aid in
-    studying their performance._]
-
-  A TYPICAL HEAT ENGINE
-    HEAT IN
-    HEAT SOURCE
-      REACTOR, BOILER
-    ELECTRICITY OUT
-    ENERGY CONVERTER
-    PUMP
-    FLUID PIPE
-    RADIATOR
-    WASTE HEAT OUT
-  PRESSURE-VOLUME DIAGRAM
-    HEAT IN
-    ENERGY OUT
-    GAS PRESSURE
-    WASTE HEAT OUT
-    GAS VOLUME
-
-Direct conversion devices are no exception. Consequently, every
-thermoelectric element or thermionic converter will have to provide for
-the disposition of waste heat. The designer will try, however, to make
-the engine efficiency high so that the waste heat will be small. Figure
-4 shows the extensive waste heat radiator on a SNAP 50 power plant
-planned for deep space missions.
-
-    [Illustration: Figure 4 _Model of SNAP 50 power plant planned for
-    deep space missions showing extensive waste heat radiator. The
-    system will provide 300 to 1000 kilowatts of electrical power._]
-
-
-Carnot Efficiency
-
-In 1824 Sadi Carnot, a young French engineer, conceived of an idealized
-heat engine. This ideal engine had an efficiency given by
-
-                     e = 1 - T_c/T_h = (T_h - T_c)/T_h
-
-  where
-    e = the so-called Carnot efficiency (no units)
-    T_c = the temperature of the waste heat reservoir (in degrees
-              Kelvin, °K[4])
-    T_h = the temperature of the heat source (in °K)
-
-Unhappily, T_c cannot be made zero (and e therefore made equal to 1,
-which is 100% efficiency). Physicists have shown absolute zero to be
-unattainable, although they have approached to within a hundredth of a
-degree in the laboratory.
-
-Waste heat, since it must be rejected to the surrounding atmosphere,
-outer space, or water (rivers, the ocean, etc.), must be rejected at T_c
-greater than 300°K. The reason for this is that these physical
-reservoirs have average temperatures around 300°K (about 80°F)
-themselves. The fact that T_c must be 300°K or more is a basic
-limitation on the Carnot efficiency. The loss in efficiency with
-increased T_c explains why a jet plane has a harder job taking off on a
-hot day.
-
-One way to improve the Carnot efficiency, which is the maximum
-efficiency for any heat engine, is to raise T_h as high as possible
-without melting the engine. For a coal-fired electrical power plant, T_h
-= 600°K and T_c = 300°K, so that
-
-                      e = 1 - 300/600 = 0.5 = 50%
-
-The actual efficiency is somewhat less than this ideal value because
-some power is diverted to pumps and other equipment and to unavoidable
-heat losses. Later on, we shall see that magnetohydrodynamic (MHD)
-generators hold prospects for increasing T_h by hundreds of degrees.
-
-Everything that has been said about the Second Law of Thermodynamics
-(You can’t even break even) applies to heat engines, where we begin with
-thermal energy. Suppose instead that we start with kinetic or chemical
-energy and convert it into electricity without turning it into heat
-first. We can then escape the Carnot efficiency strait jacket. Chemical
-batteries perform this trick. So do fuel cells, solar cells, and many
-other direct conversion devices we shall discuss. Thus, we circumvent
-the Carnot efficiency limitation by using processes to which it does not
-apply.
-
-
-                               Problem 3
-
-  Some space power plants contemplate using the space cabin heat (T_h =
-  300°K) to drive a heat engine which rejects its waste heat to the
-  liquid-hydrogen rocket fuel stored at T_c = 20°K. What would be the
-  Carnot efficiency of this engine?
-
-
-
-
-                           THERMOELECTRICITY
-
-
-After 140 Years: Seebeck Makes Good
-
-The oldest direct conversion heat engine is the thermocouple. Take two
-different materials (typically, two dissimilar metal wires), join them,
-and heat the junction. A voltage, or electromotive force, can be
-measured across the unheated terminals. T. J. Seebeck first noticed this
-effect in 1821 in his laboratory in Berlin, but, because of a mistaken
-interpretation of what was involved, he did not seek any practical
-application for it. Only recently has any real progress been made in
-using his discovery for power production. To use the analogy of A. F.
-Joffe, the Russian pioneer in this field, thermoelectricity lay
-undisturbed for over a hundred years like Sleeping Beauty. The Prince
-that awoke her was the semiconductor.
-
-As long as inefficient metal wires were used, textbook writers were
-correct in asserting that thermoelectricity could never be used for
-power production. The secret of practical thermoelectricity is therefore
-the creation of better thermoelectric materials. (Creation is the right
-word since the best materials for the purpose do not exist in nature.)
-To perform this alchemy, we first have to understand the Seebeck effect.
-
-
-Electrons and Holes
-
-Let’s examine the latticework of atoms that make up any solid material.
-In electrical insulators all the atoms’ outer electrons[5] are held
-tightly by valence bonds to the neighboring atoms. In contrast, any
-metal has many relatively loose electrons which can wander freely
-through its latticework. This is what makes metals good conductors.
-
-
-THERMOELECTRICITY
-
-    [Illustration: Figure 5 _Thermoelectric couple made from p- and
-    n-type semiconductors. The impurity atoms (I) are different in each
-    leg and contribute an excess or deficiency of valence electrons.
-    Heat drives both holes and electrons toward the cold junction._]
-
-    T_c WASTE HEAT OUT
-    ELECTRONS
-    LOAD
-    COLD JUNCTION
-    HOLES
-    ELECTRONS
-    _p_ SEMICONDUCTOR
-    _n_ SEMICONDUCTOR
-    HOT JUNCTION
-    T_h HEAT IN
-  Simplified Sketch of Atomic Lattice
-    HOLE
-    ELECTRON
-    VALENCE BONDS
-    SEMICONDUCTOR LATTICES
-    I = Impurity atom
-
-Figure 5 suggests the latticework of a _semiconductor_. It is called a
-semiconductor because its conductivity falls far short of that of the
-metals. The few electrons available for carrying electricity are
-supplied by the deliberately introduced impurity atoms, which have more
-than enough electrons to satisfy the valence-bond requirements of the
-neighboring atoms. Without the impurities, we would have an insulator.
-With them, we have an _n_-type semiconductor. The _n_ is for the extra
-_negative_ electrons.
-
-A _p_- or _positive_-type semiconductor is also included in Figure 5.
-Here the impurity atom does not have enough valence electrons to satisfy
-the valence-bond needs of the surrounding lattice atoms. The lattice has
-been short-changed and is, in effect, full of _positive holes_.
-Strangely enough, these holes can wander through the material just like
-positive charges.
-
-The electron-hole model does not have the precision the physicist likes,
-but it helps us to visualize semiconductor behavior.
-
-The Seebeck effect is demonstrated when pieces of _p_- and _n_-type
-material are joined as shown in Figure 5. Heat at the hot junction
-drives the loose electrons and holes toward the cold junction. Think of
-the holes and electrons as gases being driven through the latticework by
-the temperature difference. A positive and a negative terminal are thus
-produced, giving us a source of power. The larger the temperature
-difference, the bigger the voltage difference. Note that just one
-thermocouple _leg_ can produce a voltage across its length, but
-_couples_ made from _p_ and _n_ legs are superior.
-
-
-Practical Thermoelectric Power Generators
-
-The first nuclear-heated thermoelectric generator was built in 1954 by
-the Atomic Energy Commission’s Mound Laboratory in Miamisburg, Ohio. It
-used metal-wire thermocouples. In contrast, the SNAP 3 series
-thermocouples shown in Figure 1 are thick lead telluride (PbTe)
-semiconductor cylinders about two inches long. In contrast to the
-thermocouple wires’ efficiency of less than 1%, SNAP 3 series generators
-have overall efficiencies exceeding 5%. This value is still low compared
-to the 35-40% obtained in a modern steam power plant, but SNAP 3
-generators can operate unattended in remote localities where steam
-plants would be totally unacceptable.
-
-Look again at the thermoelements in Figure 1 and the schematic, Figure
-5. Underlying the apparent simplicity of the thermoelectric generator
-are extensive development efforts. The Figure 1 thermoelectric couple,
-for example, shows the fruits of thousands of experimental brazing
-tests. It turns out to be uncommonly difficult to fasten thermoelectric
-elements to the so-called _hot shoe_ (metal plate) at the bottom. The
-joint has to be strong, must withstand high temperatures, and must have
-low electrical resistance. We see also that the elements are encased in
-mica sleeves to prevent chemical disturbance of the delicate balance of
-impurities in the semiconductor by the surrounding gases. A further
-complication is the extreme fragility of the elements, and this has yet
-to be overcome.
-
-Nuclear thermoelectric generators that provide small amounts of
-electrical power have already been launched into space aboard Department
-of Defense satellites (Figure 12), installed on land stations in both
-polar regions, and placed under the ocean.[6] Propane-fueled
-thermoelectric generators, such as shown in Figure 6, are now on the
-market for use in camping equipment, in ocean buoys, and in remote spots
-where only a few watts of electricity are needed. The Russians have long
-manufactured a kerosene lamp with thermoelements placed in its stack for
-generating power in wilderness areas.
-
-    [Illustration: Figure 6 GENERAL PURPOSE GENERATOR
-    _Commercially available thermoelectric generators using propane fuel
-    can provide more than enough electrical power to operate a portable
-    TV set._
-                      Courtesy Minnesota Mining & Manufacturing Company.]
-
-For the present the role of thermoelectric power appears to be one of
-special uses such as those just mentioned. When higher efficiencies are
-attained, thermoelectric power may, one day, supplant dynamic conversion
-equipment in certain low-power applications regardless of location.
-
-
-
-
-                         THERMIONIC CONVERSION
-
-
-“Boiling” Electrons Out of Metals
-
-Like the thermoelectric element, the thermionic converter is a heat
-engine. In its simplest form it consists of two closely spaced metallic
-plates and resembles the diode radio tube. Whereas thermoelectric
-elements depend on heat to drive electrons and holes through
-semiconductors to an external electricity-using device or _load_, the
-salient feature of the thermionic diode is _thermionic emission_,[7] or,
-simply, the boiling-off of electrons from a hot metal surface. The
-thermionic converter shown in Figure 7 powers a small motor when heated
-by a torch.
-
-Metals, as we have already seen, have an abundance of loosely bound
-conduction electrons roaming the atomic latticework. These electrons are
-easily moved by electric fields while within the metal; but it takes
-considerably more energy to boil them out of the metal into free space.
-Work has to be done against the electric fields set up by the surface
-layer of atoms, which have unattached valence bonds on the side facing
-empty space.
-
-The energy required to completely detach an electron from the surface is
-called the metal’s _work function_. In the case of tungsten, for
-example, the work function is about 4.5 electron volts[8] of energy.
-
-    [Illustration: Figure 7 _Vacuum type thermionic converter in
-    operation._
-                                      Courtesy General Electric Company.]
-
-As we raise the temperature of a metal, the conduction electrons in the
-metal also get hotter and move with greater velocity. We may think of
-some of the electrons in a metal as forming a kind of _electron gas_.
-Some electrons will gain such high speeds that they can escape the metal
-surface. This happens when their kinetic energy exceeds the metal’s work
-function.
-
-Now that we have found a way to force electrons out of the metal, we
-would like to make them do useful electrical work. To do this we have to
-push the electrons across the gap between the plates as well as create a
-voltage difference to go with the hoped-for current flow.
-
-
-Reducing the Space Charge
-
-The emitted or boiled-off electrons between the converter plates (Figure
-8) form a cloud of negative charges that will repel subsequently emitted
-electrons back to the emitter plate unless counteraction is taken. To
-circumvent these _space charge_ effects, we fill the space between the
-plates with a gas containing positively charged particles. These mix
-with the electrons and neutralize their charge. The mixture of
-positively and negatively charged particles is called a _plasma_.
-
-The presence of the plasma makes the gas a good conductor. The emitted
-electrons can now move easily across it to the collector where, to
-continue the gas analogy, they condense on the cooler surface.
-
-    [Illustration: Figure 8 THERMIONIC CONVERSION
-    _Thermionic converters may be flat-plate types or cylindrical types.
-    The cylindrical converter (a) is an experimental type for ultimate
-    use in nuclear reactors._
-                              Courtesy Los Alamos Scientific Laboratory.]
-
-  a
-    INSULATOR
-    COOLED COLLECTOR
-    INCANDESCENT URANIUM
-    FUEL ELEMENT
-    CESIUM PLASMA
-    CIRCULATING COOLANT
-    VACUUM INSULATOR
-    CESIUM POOL
-  b
-    WASTE HEAT OUT
-    LOAD
-    ELECTRONS
-    LOW WORK FUNCTION COLLECTOR
-    T_c
-    CESIUM ION
-    PLASMA FILLED GAP
-    BOILED OFF ELECTRONS
-    HIGH WORK FUNCTION EMITTER
-    T_c
-    HEAT IN
-
-
-Result: A Plasma Thermocouple
-
-Unless a voltage difference exists across the plates, no external work
-can be done. In the thermocouple the voltage difference was caused by
-the different electrical properties of the _p_ and _n_ semiconductors.
-Both the emitter and collector in the thermionic converter are good
-metallic conductors rather than semiconductors, so a different tack must
-be taken.
-
-The key is the use of an emitter and a collector with different work
-functions. If it takes 4.5 electron volts to force an electron from a
-tungsten surface and if it regains only 3.5 electron volts when it
-condenses on a collector with a lower work function, then a voltage drop
-of 1 volt exists between the emitter and collector.
-
-To summarize, then, the thermionic emission of electrons creates the
-potentiality of current flow. The difference in work functions makes the
-thermionic converter a power producer.
-
-There is an interesting comparison that helps describe this phenomenon.
-Consider the emitter to be the ocean surface and the collector a
-mountain lake. The atmospheric heat engine vaporizes ocean water and
-carries it to the cooler mountain elevations, where it condenses as rain
-which collects in lakes. The lake water as it runs back toward sea level
-then can be made to drive a hydroelectric plant with the gravitational
-energy it has gained in the transit. The thermionic converter is similar
-in behavior: hot emitter (corresponding to the sun-heated ocean); cooler
-collector (lake); electron gas (water); different electrical voltages
-(gravity). Without gravity the river would not flow, and the production
-of electricity would be impossible.
-
-
-Thermionic Power in Outer Space
-
-Thermionic converters for use in outer space may be heated by the sun,
-by decaying radioisotopes, or by a fission reactor. Thermionic
-converters can also be made into concentric cylindrical shells (Figure
-8a) and wrapped around the uranium fuel elements in nuclear reactors.
-The waste heat in this case would be carried out of the reactor to a
-separate radiator[9] by a stream of liquid metal. Since thermionic
-converters can operate at much higher temperatures than thermoelectric
-couples or dynamic power plants, the radiator temperature, T_c, will
-also be higher. Consequently, space power plants using thermionic
-converters will have small radiators. Once thermionic converters are
-developed which have high reliability and long life, they will provide
-the basis for a new series of lighter, more efficient space power
-plants.
-
-
-
-
-                     MAGNETOHYDRODYNAMIC CONVERSION
-
-
-Big Word, Simple Concept
-
-Magnetohydrodynamic (MHD) conversion is very unlike thermoelectric or
-thermionic conversion. The MHD generators use high-velocity electrically
-conducting gases to produce power and are generically closer to dynamic
-conversion concepts. The only concept they carry forward from the
-preceding conversion ideas is that of the _plasma_, the electrically
-conducting gas. Yet they are commonly classified as _direct_ because
-they replace the rotating turbogenerator of the dynamic systems with a
-stationary pipe or _duct_.
-
-    [Illustration: Figure 9 _In the MHD duct (a), the electrons in the
-    hot plasma move to the right under influence of force F in the
-    magnetic field B. The electrons collected by the right-hand side of
-    the duct are carried to the load. In a wire in the armature of a
-    conventional generator (b) the electrons are forced to the right by
-    the magnetic field._]
-
-  a
-    MHD Duct
-    HOT PLASMA IN
-    COOL GAS OUT TO RADIATOR
-    Magnetic Field
-    LOAD
-    ELECTRONS
-  b
-    CONVENTIONAL GENERATOR
-    SHAFT
-    LOAD
-    Magnetic Field
-    ARMATURE WIRE
-    ELECTRONS
-
-In the conventional dynamic generator, an electromotive force is created
-in a wire that cuts through magnetic lines of force, as shown in Figure
-9b. It may be helpful to visualize the conduction electrons as leaving
-one end of the wire and moving to the other under the influence of the
-magnetic field.
-
-The force on the electrons in the wire is given by
-
-                                  F = qvB
-
-  where
-    F = the force (in newtons[10])
-    q = the charge on the electron (1.6 × 10⁻¹⁹ coulomb)
-    v = the wire’s velocity (in meters per second)
-    B = the magnetic field strength (in webers per square meter[10])
-
-The surge of electrons along the length of the wire sets up a voltage
-difference across the ends of the wire. A generator uses this difference
-to convert the kinetic energy of the moving wire or armature into
-electrical energy. The wire is kept spinning by the shaft which is
-connected to a turbine driven by steam or water.
-
-Let us try to eliminate the moving part, the generator armature. What we
-need is a moving conductor that has no shaft, no bearings, no wearing
-parts. The substance that meets these requirements is the plasma.
-Examine Figure 9a. The MHD generator substitutes a moving, conducting
-gas for the wires. Under the influence of an external magnetic field,
-the conduction electrons move through the plasma to one side of the duct
-which carries electrical power away to the load.
-
-The MHD generator gets its energy from an expanding, hot gas; but,
-unlike the turbogenerator, the heat engine and generator are united in
-the static duct. The gradual widening of the duct shown in Figure 9a
-reflects the lower pressure, cooler plasma at the duct’s end. Some of
-the plasma’s thermal energy content has been tapped off by the duct’s
-electrodes as electrical power.
-
-
-The Fourth State of Matter
-
-Plasma can be created by temperatures over 2000°K. At this temperature
-many high-velocity gas atoms collide with enough energy to knock
-electrons off each other and thus become ionized. The material thus
-created, shown as a glowing gas in Figure 10, does not behave
-consistently as any of the three familiar states of matter: solid,
-liquid, or gas. Plasma has been called a _fourth state of matter_. Since
-we have difficulty in containing such high temperatures on earth, we
-adopt the strategy of _seeding_. In this technique gases that are
-ordinarily difficult to ionize, like helium, are made conducting by
-adding a fraction of a percent of an alkali metal such as potassium.
-Alkali metal atoms have loosely bound outer electrons and quickly become
-ionized at temperatures well below 2000°K.
-
-    [Illustration: Figure 10 _Glowing plasma in experimental device at
-    General Atomic’s John Jay Hopkins Laboratory, San Diego. T-shaped
-    plasma gun provides data for research in thermonuclear fusion._
-                       Courtesy Texas Atomic Energy Research Foundation.]
-
-A helium-potassium mixture is a good enough conductor for use in an MHD
-generator. In this plasma the electrons move rapidly under the influence
-of the applied fields, though not as well as in metals. The positive
-ions move in the opposite direction from the electrons, but the
-electrons are much lighter and move thousands of times faster thus
-carrying the bulk of the electrical current.
-
-
-MHD Power Prospects
-
-The MHD duct is not a complete power plant in itself because, after
-leaving the duct, the stream of gas must be compressed, heated, and
-returned to the duct. Very high temperature materials and components
-must be developed for this kind of service. Moreover, while the duct is
-simple in concept, it must operate at very high temperatures in the
-presence of the corrosive alkali metals. This presents us with difficult
-materials problems. When the problems are solved, probably within the
-next decade, MHD power plants should be able to provide reliable power
-with high efficiency. They may then serve in large space power plants,
-and, most important, they may provide cheaper electricity for general
-use through their higher temperatures and greater efficiencies.
-
-
-
-
-                           CHEMICAL BATTERIES
-
-
-Electricity from the Chemical Bond
-
-If you vigorously knead a lemon to free the juices and then stick a
-strip of zinc in one end and a copper strip in the other, you can
-measure a voltage across the strips. Electrons will flow through the
-load without the inconvenience of having to supply heat. You have made
-yourself a chemical battery.
-
-The chemical battery was the first direct conversion device. Two hundred
-years ago it was the scientists’ only continuous source of electricity.
-
-Since the chemical battery does not need heat for its operation, it is
-logical to ask what makes the current flow. Where does the energy come
-from?
-
-The battery has no semiconductors, but, like the thermoelectric couple
-and the thermionic diode, it uses dissimilar materials for its
-electrodes. A conducting fluid or solid is also present to provide for
-the passage of current between the electrodes. In the example of the
-lemon, the copper and zinc are the dissimilar electrodes, and the lemon
-juice is the conducting fluid or _electrolyte_ that supplies positive
-and negative ions. The battery derives its energy from its complement of
-chemical fuel. The voltage difference arises because of the different
-strengths of the chemical bonds. The chemical bond is basically an
-electrostatic one; some atoms have stronger electrical affinities than
-others.
-
-
-Chemical Reactions Used in Batteries and Fuel Cells
-
-Consider the following chemical reactions of common batteries together
-with some fuel cell reactions which will be discussed further in the
-next section.
-
-  Battery Reactions
-    Pb + PbO₂ + 2H₂SO₄ ⇔ 2PbSO₄ + 2H₂O
-    Fe + NiO₂ ⇔ FeO + NiO
-    Zn + AgO + H₂O ⇔ Ag + Zn(OH)₂
-    Pb + Ag₂O ⇔ PbO + 2Ag
-  Fuel Cell Reactions
-    2LiH ⇔ 2Li + H₂
-    2CuBr₂ ⇔ 2CuBr + Br₂
-    2H₂ + O₂ ⇔ 2H₂O (Bacon cell)
-    PbI₂ ⇔ Pb + I₂
-
-In principle all these reactions are the same as those going on inside
-the lemon, although each type of cell produces a slightly different
-voltage because of the varying chemical affinities of the atoms and
-molecules involved. There are literally hundreds of materials which can
-be used for electrolytes and electrodes.
-
-No heat needs to be added as the electrostatic chemical bonds are broken
-and remade in a battery to generate electrical power. The chemical
-reaction energy is transferred to the electrical load with almost 100%
-efficiency. The Carnot cycle is no limitation here; only “cold”
-electrostatic forces are in action. The reactions cannot go on forever,
-however, because the battery supplies the energy converter with a very
-limited supply of fuel. Eventually the fuel is consumed and the voltage
-drops to zero. This deficiency is remedied by the fuel cell in which
-fuel is supplied continuously.
-
-
-An Old Standby in Outer Space
-
-Almost every satellite and space vehicle has a chemical battery aboard.
-It is not there so much for continuous power production but as a
-rechargeable electrical accumulator or reservoir to provide electricity
-during peak loads. The battery is also needed to store energy for use
-during the periods when solar cells are in the earth’s shadow and
-therefore inoperative. In this capacity the dependable old battery
-serves the most modern science very well indeed.
-
-
-
-
-              THE FUEL CELL: A CONTINUOUSLY FUELED BATTERY
-
-
-Potential Fuels
-
-The battery has a very close relative, the fuel cell. Unlike the battery
-the fuel cell has a continuous supply of fuel.
-
-    [Illustration: Figure 11 _This diagram shows how a hydrogen-oxygen
-    fuel cell works. The chemical battery works in the same way, except
-    that the chemicals are different and are not continuously supplied
-    from outside the cell. The water produced by the H-O cell shown can
-    be used for drinking on spaceships._]
-
-  ANODE H₂ IN
-  CATHODE O₂ IN
-  ELECTRONS
-  LOAD
-  KOH ELECTROLYTE
-  K⁺ ION
-  OH⁻ ION
-  NEGATIVE ION FLOW
-  40H⁻ + 2H₂ ⇒ 4H₂O + 4e
-  O₂ + 2H₂O + 4e ⇒ 40H⁻
-
-The hydrogen-oxygen cell of Figure 11 is typical of all fuel cells. It
-essentially burns hydrogen and oxygen to form water. If the hydrogen and
-oxygen can be supplied continuously and the excess water drained off, we
-can greatly extend the life of the battery. The fuel cell accomplishes
-this. Fueled _electrical_ cell would be more descriptive since the
-physical principles are identical with those of the battery.
-
-Perhaps the most challenging task contemplated for the fuel cell is to
-bring about the consumption of raw or slightly processed coal, gas, and
-oil fuels with atmospheric oxygen. If fuel cells can be made to use
-these abundant fuels, then the high natural conversion efficiency of the
-fuel cells will make them economically superior to the lower efficiency
-steam-electric plants now in commercial service.
-
-So far we have dwelt on the fuel cell as a cold energy conversion device
-that is _not_ limited by the Carnot efficiency. A variation on this
-theme is possible. Take a hydrogen iodide (HI) cell, and heat the HI to
-2000°K. Some of the HI molecules will collide at high velocities and
-dissociate into hydrogen and iodine: 2HI = H₂ + I₂; the higher the
-temperature, the more the dissociation. By separating the hydrogen and
-iodine gases and returning them for recycling to the fuel cell where
-they are recombined, we have eliminated the fuel supply problem and
-created a _regenerative_ fuel cell. We have, however, also reintroduced
-the heat engine and the Carnot cycle efficiency. The thermally
-regenerative fuel cell is a true heat engine using a dissociating gas as
-the working fluid.
-
-
-Scheme for Project Apollo
-
-Most of the impetus for developing the fuel cell as a practical device
-comes from the space program. The cell has admirable properties for
-space missions that are less than a few months in duration. It is a
-clean, quiet, vibrationless source of energy. Like the battery it has a
-high electrical overload capacity for supplying power peaks and is
-easily controlled. It can even provide potable water for a crew if the
-Bacon H - O cell is used. For short missions where large fuel supplies
-are not needed, it is also among the lightest power plants available.
-
-These compelling advantages have led the National Aeronautics and Space
-Administration to choose the fuel cell for some of the first manned
-space ventures. Project Apollo, the manned lunar landing mission, is the
-most notable example. Here the fuel cell will be not only an energy
-source, but also part of the ecological cycle which keeps the crew
-alive.
-
-
-                               Problem 4
-
-  A manned space vehicle requires an average of 2 electrical kilowatts.
-  A nuclear reactor thermoelectric plant having a mass of 1000
-  kilograms, including shielding, can supply this power for 10,000
-  hours. The basic fuel cell has a mass of 50 kilograms and consumes ½
-  kilogram of chemicals per hour. The chemical containers weigh 25
-  kilograms. What is the longest mission where the total weight of the
-  fuel cell will be less than the weight of the nuclear power plant?
-
-
-
-
-                              SOLAR CELLS
-
-
-Photons as Energy Carriers
-
-All our fossil fuels, such as coal and oil, owe their existence to the
-solar energy stream that has engulfed the earth for billions of years.
-The power in this stream amounts to about 1400 watts per square meter at
-the earth, nearly enough to supply an average home if all the energy
-were converted to electricity. The problem is to get the sun’s rays to
-yield up their energy with high efficiency.
-
-The sun’s visible surface has a temperature around 6000°K. Any object
-heated to this temperature will radiate visible light mostly in the
-yellow-green portion of the spectrum (5500 A[11]). Our energy conversion
-device should be tuned to this wavelength.
-
-The energy packets arriving from the sun are called photons. They
-travel, of course, at the speed of light, and each carries an amount of
-energy given by
-
-                               E = hf = hc/λ
-
-  where
-    E = energy (in joules)
-    h = Planck’s constant (6.62 × 10⁻³⁴ joule-second)
-    f = the light’s frequency (in cycles per second = c/λ)
-    c = the velocity of light (300,000,000 meters per second)
-    λ = the wavelength (in meters)
-
-Using the fact that an angstrom unit is 10⁻¹⁰ meter, the energy of a
-5500 A photon could be calculated as
-
-         E = hf = hc/λ = (6.62 × 10⁻³⁴ × 3.00 × 10⁸)/(5.50 × 10⁻⁷)
-                 = 3.61 × 10⁻¹⁹ joule = 2.2 electron volts
-
-Comparing this result, 2.2 electron volts, with the energies required to
-cause atomic ionization or molecular dissociation (an electron volt or
-so), we see that it is in the right range to actuate direct conversion
-devices based on such phenomena.
-
-
-Harnessing the Sun’s Energy
-
-Historically, the sun’s energy has most often been used by concentrating
-it with a lens or mirror and then converting it to heat. We could do
-this and run a heat engine, but a more direct avenue is open.
-
-About a decade ago it was found that the junction between _p_ and _n_
-semiconductors would generate electricity if illuminated. This discovery
-led to the development of the _solar cell_, a thin, lopsided sandwich of
-silicon semiconductors. As shown in Figure 12, the top semiconductor
-layer exposed to the sun is extremely thin, only 2.5 microns. Solar
-photons can readily penetrate this layer and reach the junction
-separating it from the thick main body of the solar cell.
-
-    [Illustration: Figure 12 THE SOLAR CELL
-    _The photograph shows the solar cell in use on a satellite. The
-    spherical, radioisotope, thermoelectric generator at the bottom of
-    the satellite is used to supplement the solar cells. In the solar
-    cell, hole-electron pairs are created by solar photons in the
-    vicinity of a p-n junction._
-             Courtesy U. S. Air Force and National Aeronautics and Space
-                                                         Administration.]
-
-  _p_ SILICON
-  _n_ SILICON
-  ELECTRON-MOLE PAIRS
-  JUNCTION
-  PHOTONS FROM SUN OR RADIOISOTOPE
-  ELECTRONS
-  ENERGY OUT
-
-Whenever _p-_ and _n-_type semiconductors are sandwiched together a
-voltage difference is created across the junction. The separated holes
-and electrons in the two semiconductor regions establish this electric
-field across the junction. Unfortunately, there are usually no current
-carriers in the immediate vicinity of the junction so that no power is
-produced.
-
-The absorption of solar photons in the vicinity of the junction will
-create current carriers, as the photons’ energy is transformed into the
-potential energy of the hole-electron pairs. These pairs would quickly
-recombine and give up their newly acquired potential energy if the
-electric field existing across the junction did not whisk them away to
-an external load.
-
-The solar cell produces electricity when hole-electron pairs are formed.
-Any other phenomenon that creates such pairs will also generate
-electricity. The source of energy is irrelevant so long as the current
-carriers are formed near the junction. Thus, particles emitted by
-radioactive atoms can also produce electricity from solar cells,
-although too much bombardment by such particles can damage the cell’s
-atomic structure and reduce its output.
-
-The solar cell is not a heat engine. Yet it loses enough energy so that
-the sun’s energy is converted at less than 15% efficiency. Losses
-commonly occur because of the recombination of the hole-electron pairs
-before they can produce current, the absorption of photons too far from
-the junction, and the reflection of incident photons from the top
-surface of the cell. Despite these losses solar cells are now the
-mainstay of nonpropulsive space power.
-
-
-
-
-                           NUCLEAR BATTERIES
-
-
-Energy from Nuclear Particles
-
-As we have seen, solar cells are able to convert the kinetic energy of
-charged nuclear particles directly into electricity, but a simpler and
-more straightforward way of doing this exists. This involves direct use
-of the flow of charged particles as current.
-
-The _nuclear battery_ shown in Figure 13 performs this trick. A central
-rod is coated with an electron-emitting radioisotope (a beta-emitter;
-say, strontium-90). The high-velocity electrons emitted by the
-radioisotope cross the gap between the cylinders and are collected by a
-simple metallic sleeve and sent to the load. Simple, but why don’t space
-charge effects prevent the electrons from crossing the gap as they do in
-the thermionic converter? The answer lies in the fact that the nuclear
-electrons have a million times more kinetic energy than those boiled off
-the thermionic converter’s emitter surface. Consequently, they are too
-powerful to be stopped by any space charge in the narrow gap.
-
-Nuclear batteries are simple and rugged. They generate only microamperes
-of current at 10,000 to 100,000 volts.
-
-    [Illustration: Figure 13 A NUCLEAR BATTERY
-    _The nuclear battery depends upon the emission of charged particles
-    from a surface coated with a radioisotope. The particles are
-    collected on another surface._]
-
-  ENERGY OUT
-  INSULATOR
-  LAYER OF BETA-EMITTING RADIOISOTOPE
-  VACUUM
-
-
-Double Conversion
-
-In the earlier description of the energy conversion matrix, we saw that
-we could go through the energy transformation process repeatedly until
-we obtained the kind of energy we wanted. This is exemplified in a type
-of nuclear battery which uses the so-called _double conversion_
-approach. First, the high-velocity nuclear particles are absorbed in a
-phosphor which emits visible light. The photons thus produced are then
-absorbed in a group of strategically placed solar cells, which deliver
-electrical power to the load. Although efficiency is lost at each energy
-transformation, the double conversion technique still ends up with an
-overall efficiency of from 1 to 5%, an acceptable value for power
-supplies in the watt and milliwatt ranges.
-
-
-
-
-                           ADVANCED CONCEPTS
-
-
-Ferroelectric and thermomagnetic conversion are subtle concepts which
-depend upon the gross alteration of a material’s physical properties by
-the application of heat. Devices employing such concepts are true heat
-engines. Instead of the gaseous and electronic working fluids used in
-the other direct conversion concepts, the ferroelectric and
-thermomagnetic concepts employ patterns of atoms and molecules that are
-actually rearranged periodically by heat.
-
-
-Ferroelectric Conversion
-
-Ferroelectric conversion makes use of the peculiar properties of
-_dielectric_[12] materials. Barium titanate, for example, has good
-dielectric properties at low temperatures, but, when its temperature is
-raised to more than 120°C, the properties get worse rapidly. We cannot
-discuss dielectric behavior thoroughly in this booklet; suffice it to
-say that in this process heat is absorbed in a realignment of molecules
-within the barium titanate latticework.
-
-If we now place a slab of barium titanate between the two plates of an
-electrical condenser and charge the condenser, as shown in Figure 14, we
-have a unique way of converting heat into electricity directly. When the
-barium titanate is heated above its _Curie point_[13] of 120°C, the
-condenser’s capacitance is radically reduced as the dielectric constant
-falls. The condenser is forced to discharge and move electrons through
-an external circuit consisting of the load and the original source of
-charge. Useful electrical energy is delivered during this step. Figure
-14 shows the process schematically and mathematically. When the
-dielectric is cooled, waste heat is given up by the barium titanate, and
-the cycle is complete.
-
-    [Illustration: Figure 14 FERROELECTRIC ENERGY CONVERSION
-    _The ferroelectric converter is really an electrical capacitor whose
-    capacitance is changed by temperature. When heat is added,
-    capacitance drops, voltage rises, and the capacitor is made to
-    discharge through the load. CYCLE: ① Switch #1 closed, #2 open.
-    Condenser charges from battery to charge Q₂ at voltage V₁ with
-    capacity C₁. ② All switches open. Heat added, capacity changes from
-    C₁ to C₂, charge remains constant, so voltage changes from V₁ to V₂.
-    ③ Switch #2 closed, #1 open. Condenser discharges through load and
-    battery to charge Q₁ at voltage V₁ with capacity C₂. ④ All switches
-    open. Heat rejected, capacity changes from C₂ to C₁, charge remains
-    constant, so voltage changes from V₁ to V₀. CYCLE THEN REPEATS.
-    Energy supplied from battery each cycle is E₁. Energy delivered to
-    load and battery each cycle is E₂. Net energy converted is then
-    E₂ - E₁, the difference in the shaded areas._]
-
-  (a) CIRCUIT
-    HEAT IN
-    BARIUM TITANATE DIELECTRIC
-    WASTE HEAT OUT
-    SWITCH #2
-    LOAD
-    SWITCH #1
-    BATTERY
-  (b) CYCLE DIAGRAM
-    charge
-    volts
-    Q₂, Q₁, E₁, E₂, V₀ V₁  V₂
-    GENERAL INFORMATION:
-      C₂ < C₁
-      V = Q/C
-
-
-Thermomagnetic Conversion
-
-The _analog_[14] of ferroelectricity is ferromagnetism. A converter
-employing similar principles to those in ferroelectricity can be made
-using an electrical _inductance_ with a ferromagnetic core. When the
-temperature of the ferromagnetic material is raised above its Curie
-point, its magnetic _permeability_ drops quickly, causing the magnetic
-field to collapse partially. Energy may be delivered to an external load
-during this change. Instead of energy being stored in an electrostatic
-field, it is stored in a magnetic field.
-
-Ferroelectric and thermomagnetic conversion both represent a class of
-energy transformations which involve internal molecular or crystalline
-rearrangements of solids. There is no change of phase as in a steam
-engine, but the energy changes are there nevertheless. In thermodynamics
-such internal geometrical changes are called _second-order_ transitions,
-as opposed to the _first-order_ transitions observed with heat engines
-using two-phase working fluids like water/steam.
-
-
-On the Frontier
-
-Other potential energy conversion schemes are being investigated by
-scientists and engineers. Those listed in the Energy Conversion Matrix
-(Figure 2) only scratch the surface.
-
-In particular, we are just learning how to manipulate photons. There are
-photochemical, photoelectric, and even photomechanical transformations.
-These have hardly been tapped.
-
-Consider the reaction when an electron and its antimatter equivalent,
-the positron, meet. They mutually annihilate each other in a burst of
-energy! This energy will be harnessed someday.
-
-What energy conversion device are we going to use to completely convert
-mass into energy? The energy requirements for interstellar exploration
-are so great that these voyages will be impossible unless a new device
-is found that can completely transform mass into energy.
-
-Then again, we haven’t the faintest idea of how to control gravitational
-energy, but we may learn.
-
-The panorama is endless.
-
-
-                               Problem 5
-
-  A 1,000,000-kilogram spaceship takes off for Alpha Centauri, our
-  nearest star, 4.3 light years away. If it accelerates to nine-tenths
-  the velocity of light, what is its kinetic energy? How much fuel mass
-  will have to be completely converted to energy to acquire this
-  velocity?
-
-
-
-
-                          SUGGESTED REFERENCES
-
-
-Articles
-
-Fuel Cells, Leonard G. Austin, _Scientific American_, 201: 72 (October
-      1959). A survey of the different types.
-
-Nuclear Power in Outer Space, William R. Corliss, _Nucleonics_, 18: 58
-      (August 1960). A review of all nuclear space power plants.
-
-Fuel Cells for Space Vehicles, M. G. Del Duca, _Astronautics_, 5: 36
-      (March 1960).
-
-Fuel Cells, E. Gorin and H. L. Recht, _Chemical Engineering Progress_,
-      55: 51 (August 1959).
-
-Thermionic Converters, Karl G. Hernqvist, _Nucleonics_, 17: 49 (July
-      1959).
-
-The Revival of Thermoelectricity, Abram F. Joffe, _Scientific American_,
-      199: 31 (November 1958). Excellent historical and technical
-      review.
-
-The Photovoltaic Effect and Its Utilization, P. Rappaport, _RCA Review_,
-      20: 373 (September 1959). Recommended for advanced students.
-
-The Prospects of MHD Power Generation, Leo Steg and George W. Sutton,
-      _Astronautics_, 5: 22 (August 1960).
-
-Conversion of Heat to Electricity by Thermionic Emission, Volney C.
-      Wilson, _Journal of Applied Physics_, 30: 475 (April 1959).
-      Recommended for advanced students.
-
-Improved Solar Cells Planned for IMP-D, R. D. Hibben, _Aviation Week &
-      Space Technology_, 83: 53 (July 26, 1965).
-
-Thin-film Solar Cells Boost Output Ratio, P. J. Klass, _Aviation Week &
-      Space Technology_, 83: 67 (November 29, 1965).
-
-
-Books
-
-_Direct Conversion of Heat to Electricity_, Joseph Kaye and John A.
-      Welsh, John Wiley & Sons, Inc., New York 10016, 1960, 387 pp.,
-      $11.50. Recommended for advanced students.
-
-_Selected Papers on New Techniques for Energy Conversion_, Sumner N.
-      Levine, (Ed.), Dover Publications, Inc., New York 10014, 1961,
-      444 pp., $3.00. A reprinting of many classical papers on direct
-      conversion.
-
-_Energy Conversion for Space Power_, Nathan W. Snyder, (Ed.), Academic
-      Press, Inc., New York 10003, 1961, 779 pp., $8.50. A collection of
-      American Rocket Society papers.
-
-_Man and Energy_, Alfred Rene Ubbelohde, George Braziller, New York
-      10016, 1955, 247 pp., $5.00 (hardback); $1.25 (paperback), from
-      Penguin Books, Inc., Baltimore, Maryland 21211. A popular
-      treatment of energy and power.
-
-
-Motion Pictures
-
-The following films are produced by Educational Services, Inc., and are
-available from Modern Learning Aids, A Division of Modern Talking
-Picture Service, Inc., 3 East 54th St., New York 22, New York.
-
-  _Energy and Work_, 0311, 29 minutes, $150.
-  _Mechanical Energy and Thermal Energy_, 0312, 27 minutes, $120.
-  _Conservation of Energy_, 0313, 27 minutes, $150.
-  _Photo-Electric Effect_, 0417, 28 minutes, $220.
-
-
-
-
-                          ANSWERS TO PROBLEMS
-
-
-First, mechanical energy drives the car’s electric generator. Second,
-the electrical energy is converted into chemical energy when the battery
-is recharged.
-
-
-                       *   *   *   *   *   *   *
-
-From the kinetic energy equation we get
-
-                              v = √(2 E/m)
-
-Since the engine is 25% efficient, the energy available to propel the
-car is 48,000 × 0.25 or 12,000 joules. So
-
-           v = √(24,000/1,000) = 2√6 = 4.9 meters per second
-
-
-                       *   *   *   *   *   *   *
-
-                e = (300 - 20)/300 = 14/15 = 0.93 = 93%
-
-The crossover point, t, in hours is found by equating the nuclear power
-plant mass and that of the fuel cell with its associated fuel. The
-equation is
-
-                          1000 = 50 + 25 + ½t
-                        t = 1850 hours = 77 days
-
-
-                       *   *   *   *   *   *   *
-
-        E = ½ mv² = (10⁶(0.9 × 3 × 10⁸)²)/2 = 3.6 × 10²² joules
-
-The ship will use the same amount of energy to decelerate at its
-destination. Note that this calculation assumes a perfect efficiency in
-converting the energy of matter annihilation into the kinetic energy of
-the space ship. The mass consumed is
-
-           m = E/c² = (3.6 × 10²²)/(9 × 10¹⁶) = 4.0 × 10⁵ kg
-
-almost half the spaceship mass.
-
-
-
-
-                               Footnotes
-
-
-[1]Systems for Nuclear Auxiliary Power.
-
-[2]Described in this booklet.
-
-[3]Magnetohydrodynamics.
-
-[4]The Kelvin temperature scale starts with zero at absolute zero
-    instead of at the freezing point of water. Therefore, °K = °C + 273;
-    °K = ⁵/₉ (°F + 460).
-
-[5]Termed _valence_ or _conduction_ electrons, these are responsible for
-    chemical properties, bonds with other atoms, and the conduction of
-    electricity.
-
-[6]See the companion Understanding the Atom booklet, _Power from
-    Radioisotopes_.
-
-[7]Discovered by Thomas Edison in 1883.
-
-[8]An electron volt is equal to the kinetic energy acquired by an
-    electron accelerated through a potential difference of 1 volt. It is
-    equal to 1.6 × 10⁻¹⁹ joule.
-
-[9]In outer space, waste heat must be radiated away. The rate at which
-    heat is radiated is proportional to the fourth power of T_c
-    (Stefan-Boltzmann law).
-
-[10]The newton and the weber are mks (meter-kilogram-second) units.
-
-[11]An angstrom unit (A) is a unit of distance measurement equal to
-    10⁻¹⁰ meter.
-
-[12]Dielectric materials are nonconductors such as are those used
-    between the plates of a condenser to increase its electrical
-    capacity.
-
-[13]The Curie point is the temperature at which a material’s crystalline
-    structure radically changes and becomes less orderly.
-
-[14]Ferroelectricity and ferromagnetism are very similar. The equations
-    describing these phenomena are almost identical except that
-    capacitance is replaced by its magnetic analog, inductance, and so
-    on.
-
-
-This booklet is one of the “Understanding the Atom” Series. Comments are
-invited on this booklet and others in the series; please send them to
-the Division of Technical Information, U. S. Atomic Energy Commission,
-Washington, D. C. 20545.
-
-Published as part of the AEC’s educational assistance program, the
-series includes these titles:
-
-  _Accelerators_
-  _Animals in Atomic Research_
-  _Atomic Fuel_
-  _Atomic Power Safety_
-  _Atoms at the Science Fair_
-  _Atoms in Agriculture_
-  _Atoms, Nature, and Man_
-  _Careers in Atomic Energy_
-  _Computers_
-  _Controlled Nuclear Fusion_
-  _Cryogenics, The Uncommon Cold_
-  _Direct Conversion of Energy_
-  _Fallout From Nuclear Tests_
-  _Food Preservation by Irradiation_
-  _Genetic Effects of Radiation_
-  _Index to the UAS Series_
-  _Lasers_
-  _Microstructure of Matter_
-  _Neutron Activation Analysis_
-  _Nondestructive Testing_
-  _Nuclear Clocks_
-  _Nuclear Energy for Desalting_
-  _Nuclear Power and Merchant Shipping_
-  _Nuclear Power Plants_
-  _Nuclear Propulsion for Space_
-  _Nuclear Reactors_
-  _Nuclear Terms, A Brief Glossary_
-  _Our Atomic World_
-  _Plowshare_
-  _Plutonium_
-  _Power from Radioisotopes_
-  _Power Reactors in Small Packages_
-  _Radioactive Wastes_
-  _Radioisotopes and Life Processes_
-  _Radioisotopes in Industry_
-  _Radioisotopes in Medicine_
-  _Rare Earths_
-  _Reading Resources in Atomic Energy_
-  _Research Reactors_
-  _SNAP, Nuclear Space Reactors_
-  _Sources of Nuclear Fuel_
-  _Synthetic Transuranium Elements_
-  _The Atom and the Ocean_
-  _The Chemistry of the Noble Gases_
-  _The First Reactor_
-  _Whole Body Counters_
-  _Your Body and Radiation_
-
-A single copy of any one booklet, or of no more than three different
-booklets, may be obtained free by writing to:
-
-            USAEC, P. O. BOX 62, OAK RIDGE, TENNESSEE 37830
-
-Complete sets of the series are available to school and public
-librarians, and to teachers who can make them available for reference or
-for use by groups. Requests should be made on school or library
-letterheads and indicate the proposed use.
-
-Students and teachers who need other material on specific aspects of
-nuclear science, or references to other reading material, may also write
-to the Oak Ridge address. Requests should state the topic of interest
-exactly, and the use intended.
-
-In all requests, include “Zip Code” in return address.
-
-                Printed in the United States of America
-USAEC Division of Technical Information Extension, Oak Ridge, Tennessee
-                                May 1968
-
-
-
-
-                          Transcriber’s Notes
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-<p style='text-align:center; font-size:1.2em; font-weight:bold'>The Project Gutenberg eBook of Direct Conversion of Energy, by William R. Corliss</p>
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-This eBook is for the use of anyone anywhere in the United States and
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-<p style='display:block; margin-top:1em; margin-bottom:1em; margin-left:2em; text-indent:-2em'>Title: Direct Conversion of Energy</p>
-  <p style='display:block; margin-top:1em; margin-bottom:0; margin-left:2em; text-indent:-2em'>Author: William R. Corliss</p>
-<p style='display:block; text-indent:0; margin:1em 0'>Release Date: August 11, 2021 [eBook #66033]</p>
-<p style='display:block; text-indent:0; margin:1em 0'>Language: English</p>
-  <p style='display:block; margin-top:1em; margin-bottom:0; margin-left:2em; text-indent:-2em; text-align:left'>Produced by: Stephen Hutcheson and the Online Distributed Proofreading Team at https://www.pgdp.net </p>
-<div style='margin-top:2em; margin-bottom:4em'>*** START OF THE PROJECT GUTENBERG EBOOK DIRECT CONVERSION OF ENERGY ***</div>
-<div id="cover" class="img">
-<img id="coverpage" src="images/cover.jpg" alt="Direct Conversion of Energy" width="1000" height="1557" />
-</div>
-<div class="box">
-<h1><span class="smallest">Direct Conversion of Energy</span></h1>
-<div class="img">
-<img src="images/p01.jpg" id="ncfig1" alt="uncaptioned" width="600" height="296" />
-</div>
-<p class="center">By William R. Corliss</p>
-<p class="tbcenter"><span class="ss smaller">U.S. ATOMIC ENERGY COMMISSION
-<br />Division of Technical Information</span></p>
-<p class="tbcenter"><i class="ss"><span class="smaller">ONE OF A SERIES ON</span>
-<br />UNDERSTANDING THE ATOM</i></p>
-</div>
-<div class="pb" id="Page_i">i</div>
-<dl class="undent"><dt><span class="ssn smaller">UNITED STATES ATOMIC ENERGY COMMISSION</span></dt>
-<dt><i>Dr. Glenn T. Seaborg, Chairman</i></dt>
-<dt><i>James T. Ramey</i></dt>
-<dt><i>Dr. Gerald F. Tape</i></dt>
-<dt><i>Wilfrid E. Johnson</i></dt></dl>
-<p class="tb">Nuclear energy
-is playing a vital role
-in the life of
-every man, woman, and child
-in the United States today.
-In the years ahead
-it will affect increasingly
-all the peoples of the earth.
-It is essential
-that all Americans
-gain an understanding
-of this vital force if
-they are to discharge thoughtfully
-their responsibilities as citizens
-and if they are to realize fully
-the myriad benefits
-that nuclear energy
-offers them.</p>
-<p>The United States
-Atomic Energy Commission
-provides this booklet
-to help you achieve
-such understanding.</p>
-<p class="jr1"><img class="inline" src="images/sig.jpg" alt="Edward J. Brunenkant" width="300" height="99" />
-<br />Edward J. Brunenkant
-<br />Director
-<br />Division of Technical Information</p>
-<h2 id="toc" class="center">CONTENTS</h2>
-<dl class="toc">
-<dt><a href="#c1">INTRODUCTION</a> 1</dt>
-<dt><a href="#c2">DIRECT VERSUS DYNAMIC ENERGY CONVERSION</a> 3</dt>
-<dt><a href="#c3">LAWS GOVERNING ENERGY CONVERSION</a> 8</dt>
-<dt><a href="#c4">THERMOELECTRICITY</a> 12</dt>
-<dt><a href="#c5">THERMIONIC CONVERSION</a> 16</dt>
-<dt><a href="#c6">MAGNETOHYDRODYNAMIC CONVERSION</a> 19</dt>
-<dt><a href="#c7">CHEMICAL BATTERIES</a> 22</dt>
-<dt><a href="#c8">THE FUEL CELL: A CONTINUOUSLY FUELED BATTERY</a> 24</dt>
-<dt><a href="#c9">SOLAR CELLS</a> 26</dt>
-<dt><a href="#c10">NUCLEAR BATTERIES</a> 28</dt>
-<dt><a href="#c11">ADVANCED CONCEPTS</a> 30</dt>
-<dt><a href="#c12">SUGGESTED REFERENCES</a> 33</dt>
-<dt><a href="#c13">ANSWERS TO PROBLEMS</a> 34</dt>
-</dl>
-<p class="tb"><span class="smaller">Library of Congress Catalog Card Number: 64-61794</span></p>
-<div class="pb" id="Page_ii">ii</div>
-<h3>ABOUT THE AUTHOR</h3>
-<div class="img">
-<img src="images/p02.jpg" id="ncfig2" alt="William R. Corliss" width="433" height="599" />
-</div>
-<p><span class="ss">WILLIAM R. CORLISS</span> is an atomic
-energy consultant and writer with 12
-years of industrial experience including
-service as Director of Advanced
-Programs for the Martin
-Company&rsquo;s Nuclear Division. Mr.
-Corliss has B.S. and M.S. Degrees
-in Physics from Rensselaer Polytechnic
-Institute and the University
-of Colorado, respectively. He has
-taught at those two institutions and
-at the University of Wisconsin. He
-is the author of <i>Propulsion Systems
-for Space Flight</i> (McGraw-Hill 1960),
-<i>Space Probes and Planetary Exploration</i>
-(Van Nostrand 1965), <i>Mysteries
-of the Universe</i> (Crowell 1967), <i>Scientific Satellites</i> (GPO
-1967), and coauthor of <i>Radioisotopic Power Generation</i> (Prentice-Hall
-1964), as well as numerous articles and papers for technical
-journals and conferences. In this series he has written <i>Neutron
-Activation Analysis</i>, <i>Power Reactors in Small Packages</i>, <i>SNAP&mdash;Nuclear
-Reactor Power in Space</i>, <i>Computers</i>, <i>Nuclear Propulsion
-for Space</i>, <i>Space Radiation</i>, and was coauthor of <i>Power from Radioisotopes</i>.</p>
-<div class="pb" id="Page_1">1</div>
-<h2 id="c1"><span class="small">INTRODUCTION</span></h2>
-<p>A flashlight battery supplies electricity without moving
-mechanical parts. It converts the chemical energy of its
-contents <i>directly</i> into electrical energy.</p>
-<p>Early direct conversion devices such as Volta&rsquo;s battery,
-developed in 1795, gave the scientists Ampere, Oersted,
-and Faraday their first experimental supplies of electricity.
-The lessons they learned about electrical energy and its
-intimate relation with magnetism spawned the mighty
-turboelectric energy converters&mdash;steam and hydroelectric
-turbines&mdash;which power modern civilization.</p>
-<p>We have improved upon Volta&rsquo;s batteries and have come
-to rely on them as portable, usually small, power sources,
-but only recently has the challenge of nuclear power and
-space exploration focused our attention on new methods of
-direct conversion.</p>
-<p>To supply power for use in outer space and also at remote
-sites on earth, we need power sources that are reliable,
-light in weight, and capable of unattended Operation for long
-periods of time. Nuclear power plants using direct conversion
-techniques hold promise of surpassing conventional
-power sources in these attributes. In addition, the inherently
-<span class="pb" id="Page_2">2</span>
-silent operation of direct conversion power plants is
-an important advantage for many military applications.</p>
-<p>The Atomic Energy Commission, the Department of Defense,
-and the National Aeronautics and Space Administration
-collectively sponsor tens of millions of dollars worth
-of research and development in the area of direct conversion
-each year. In particular, the Atomic Energy Commission
-supports more than a dozen research and development
-programs in thermoelectric and thermionic energy conversion
-in industry and at the Los Alamos Scientific Laboratory,
-and other direct conversion research at Argonne National
-Laboratory and Brookhaven National Laboratory.
-Reactor and radioisotopic power plants utilizing direct conversion
-are being produced under the AEC&rsquo;s SNAP<a class="fn" id="fr_1" href="#fn_1">[1]</a> program.
-Some of these units are presently in use powering
-satellites, Arctic and Antarctic weather stations, and navigational
-buoys.</p>
-<p>Further applications are now being studied, but the cost
-of direct conversion appears too great to permit its general
-use for electric power in the near future. Direct techniques
-will be used first where their special advantages outweigh
-higher cost.</p>
-<div class="pb" id="Page_3">3</div>
-<h2 id="c2"><span class="small">DIRECT VERSUS DYNAMIC ENERGY CONVERSION</span></h2>
-<h3>Dominance of Dynamic Conversion</h3>
-<p>We live in a world of motion. A main task of the engineer
-is to find better and more efficient ways of transforming
-the energy locked in the sun&rsquo;s rays or in fuels, such as coal
-and the uranium nucleus, into energy of motion. Almost all
-the world&rsquo;s energy is now transformed by rotating or reciprocating
-machines. We couple the energy of exploding
-gasoline and air to our automobile&rsquo;s wheels by a reciprocating
-engine. The turbogenerator at a hydroelectric plant
-extracts energy from falling water and turns it into electricity.
-Such rotating or reciprocating machines are called
-<i>dynamic</i> converters.</p>
-<h3>A New Level of Sophistication: Direct Conversion</h3>
-<p>A revolution is in the making. We know now that we can
-force the heat-and-electricity-carrying electrons residing
-in matter to do our bidding without the use of shafts and
-pistons. This is a leading accomplishment of modern technology:
-energy transformation without moving parts. It is
-called <i>direct</i> conversion.</p>
-<p>The thermoelements shown above the turbogenerator in
-<a href="#fig1">Figure 1</a> illustrate the contrast between direct and dynamic
-<span class="pb" id="Page_4">4</span>
-conversion. The thermoelements convert heat into electricity
-directly, without any of the intervening machinery
-seen in the turbogenerator.</p>
-<div class="img" id="fig1">
-<img src="images/p03.jpg" alt="" width="800" height="1039" />
-<p class="pcap"><b>Figure 1</b> <i>Direct conversion devices, such as the spokelike lead telluride
-thermoelectric elements inside the SNAP 3 radioisotope generator
-shown above (courtesy Martin Company), convert heat into electricity
-without moving parts. In contrast, the SNAP 2 dynamic converter
-shown below SNAP 3 (courtesy Thompson Ramo Wooldridge, Inc.) includes
-a high-speed turbine, an electric generator, and pumps to produce
-electricity from heat. (NaK is a liquid mixture of sodium and
-potassium.)</i></p>
-</div>
-<dl class="undent pcap"><dt>DIRECT VERSUS DYNAMIC CONVERSION</dt>
-<dd>SNAP 3 LESS THAN 5 WATTS</dd>
-<dd class="t">5&Prime;</dd>
-<dd>SNAP 2 3000 WATTS</dd>
-<dd class="t">24&Prime;</dd>
-<dd class="t">ALTERNATOR ROTOR</dd>
-<dd class="t">ALTERNATOR STATOR</dd>
-<dd class="t">TURBINE ROTORS</dd>
-<dd class="t">NaK PUMP DIFFUSER</dd>
-<dd class="t">NaK PUMP ROTOR</dd>
-<dd class="t">MERCURY JET BOOSTER PUMP</dd>
-<dd class="t">MERCURY CENTRIFUGAL PUMP</dd>
-<dd class="t">MERCURY THRUST BEARING</dd>
-<dd class="t">MERCURY BEARING</dd>
-<dd class="t">MERCURY BEARING</dd></dl>
-<div class="pb" id="Page_5">5</div>
-<h3>Why is Direct Conversion Desirable?</h3>
-<p>There are places where energy conversion equipment
-must run for years without maintenance or breakdown.
-Also, there are situations where the ultimate in reliability
-is required, such as on scientific satellites and particularly
-on manned space flights. Direct conversion equipment seems
-to offer greater reliability than dynamic conversion equipment
-for these purposes.</p>
-<p>We should recognize that our belief in the superiority of
-direct conversion is based more on intuition than proof. It
-is true that direct converters will never throw piston rods
-or run out of lubricant. Yet, some satellite power failures
-have been caused by the degradation of solar cells under
-the bombardment of solar protons. The other types of direct
-conversion devices described in the following pages may
-also break down in ways as yet unknown. Still, today&rsquo;s
-knowledge gives us hope that direct conversion will be
-more reliable and trustworthy than dynamic conversion.
-Direct conversion equipment is beginning to be adopted for
-small power plants, producing less than 500 watts, designed
-to operate for long periods of time in outer space and under
-the ocean. Some day, large central-station power plants
-may use direct conversion to improve their efficiencies and
-reliabilities.</p>
-<h3>How is Energy Transformed?</h3>
-<p>What is energy and how do we change it? Energy is a
-fundamental concept of science involving the capacity for
-doing work. <i>Kinetic</i> or mechanical energy is the most obvious
-form of energy. It is defined as</p>
-<div class="verse">
-<p class="lc">E = &frac12; mv&sup2;</p>
-<p class="t0">where</p>
-<p class="t">E = energy (expressed in joules)</p>
-<p class="t">m = mass of the moving object (in kilograms)</p>
-<p class="t">v = velocity (in meters per second)</p>
-</div>
-<p>Energy can also be stored in chemical and nuclear substances
-or in the water behind a dam. In these quiescent
-states it is called <i>potential</i> energy. If the potential energy
-in a substance is abundant and easily released, the energy-rich
-substance is called a <i>fuel</i>.</p>
-<div class="pb" id="Page_6">6</div>
-<h3>ENERGY CONVERSION MATRIX</h3>
-<div class="img" id="fig2">
-<img src="images/p04.jpg" alt="" width="1200" height="878" />
-<p class="pcap"><b>Figure 2</b> <i>To find how one form of
-energy is converted into another, start
-at the proper column and move down
-until the column intersects with the desired
-row. The box at the intersection
-will give typical conversion processes
-and examples.</i></p>
-</div>
-<table class="center">
-<tr class="th"><th>FROM&rArr; </th><th>ELECTROMAGNETIC </th><th>CHEMICAL </th><th>NUCLEAR </th><th>THERMAL </th><th>KINETIC<br />(MECHANICAL) </th><th>ELECTRICAL </th><th>GRAVITATIONAL</th></tr>
-<tr class="th"><th>TO&dArr;</th></tr>
-<tr><td class="l"><b>ELECTROMAGNETIC</b> </td><td class="l"> </td><td class="l">Chemiluminescence<br />(fireflies) </td><td class="l">Gamma reactions<br />(Co&#8309;&#8312; source)<br />A-bomb </td><td class="l">Thermal radiation<br />(hot iron) </td><td class="l">Accelerating charge<br />(cyclotron)<br />Phosphor<a class="fn" id="fr_2" href="#fn_2">[2]</a> </td><td class="l">Electromagnetic radiation<a class="fn" href="#fn_2">[2]</a><br />(TV transmitter)<br />Electroluminescence </td><td class="l">Unknown</td></tr>
-<tr><td class="l"><b>CHEMICAL</b> </td><td class="l">Photosynthesis<br />(plants)<br />Photochemistry<br />(photographic film) </td><td class="l"> </td><td class="l">Radiation catalysis<br />(hydrazine plant)<br />Ionization<br />(cloud chamber) </td><td class="l">Boiling<br />(water/steam)<br />Dissociation </td><td class="l">Dissociation by radiolysis </td><td class="l">Electrolysis<br />(production of aluminum)<br />Battery charging </td><td class="l">Unknown</td></tr>
-<tr><td class="l"><b>NUCLEAR</b> </td><td class="l">Gamma-neutron reactions<br />(Be&#8313;+&gamma; &rarr; Be&#8312;+n) </td><td class="l">Unknown </td><td class="l"> </td><td class="l">Unknown </td><td class="l">Unknown </td><td class="l">Unknown </td><td class="l">Unknown</td></tr>
-<tr><td class="l"><b>THERMAL</b> </td><td class="l">Solar absorber<br />(hot sidewalk) </td><td class="l">Combustion<br />(fire) </td><td class="l">Fission<br />(fuel element)<br />Fusion </td><td class="l"> </td><td class="l">Friction<br />(brake shoes) </td><td class="l">Resistance-heating<br />(electric stove) </td><td class="l">Unknown</td></tr>
-<tr><td class="l"><b>KINETIC</b> </td><td class="l">Radiometer Solar cell<a class="fn" href="#fn_2">[2]</a> </td><td class="l">Muscle </td><td class="l">Radioactivity<br />(alpha particles)<br />A-bomb </td><td class="l">Thermal expansion<br />(turbines)<br />Internal combustion<br />(engines) </td><td class="l"> </td><td class="l">Motors<br />Electrostriction<br />(sonar transmitter) </td><td class="l">Falling objects</td></tr>
-<tr><td class="l"><b>ELECTRICAL</b> </td><td class="l">Photoelectricity<br />(light meter)<br />Radio antenna<br />Solar cell<a class="fn" href="#fn_2">[2]</a> </td><td class="l">Fuel cell<a class="fn" href="#fn_2">[2]</a><br />Batteries<a class="fn" href="#fn_2">[2]</a> </td><td class="l">Nuclear battery<a class="fn" href="#fn_2">[2]</a> </td><td class="l">Thermoelectricity<a class="fn" href="#fn_2">[2]</a><br />Thermionics<a class="fn" href="#fn_2">[2]</a><br />Thermomagnetism<a class="fn" href="#fn_2">[2]</a><br />Ferroelectricity<a class="fn" href="#fn_2">[2]</a> </td><td class="l">MHD<a class="fn" href="#fn_2">[2]</a><a class="fn" id="fr_3" href="#fn_3">[3]</a><br />Conventional generator </td><td class="l"> </td><td class="l">Unknown</td></tr>
-<tr><td class="l"><b>GRAVITATIONAL</b> </td><td class="l">Unknown </td><td class="l">Unknown </td><td class="l">Unknown </td><td class="l">Unknown </td><td class="l">Rising objects<br />(rockets) </td><td class="l">Unknown</td></tr>
-</table>
-<h3>The Energy Conversion Matrix</h3>
-<p>Forms of energy are interchangeable. When gasoline is
-burned in an automobile engine, potential energy is first
-turned into heat. A portion of this heat, say 25%, is then
-converted into mechanical motion. The remainder of the
-heat is wasted and must be removed from the engine.</p>
-<p>A multitude of processes and devices have been found
-which make these transformations from one form of energy
-to another. Many of these are listed in the blocks in <a href="#fig2">Figure 2</a>.
-Asterisks refer to direct conversion processes, the subject
-matter of this booklet.</p>
-<div class="pb" id="Page_7">7</div>
-<p>To demonstrate how this diagram is to be read, let us
-use it to trace the energy transformations involved in an
-automobile engine. We begin with sunlight because all coal
-and oil deposits (the <i>fossil fuels</i>) received their initial
-charge of energy in the form of sunlight.</p>
-<p>The first conversion, therefore, is from electromagnetic
-energy to chemical energy via photosynthesis in living
-things. We trace the transformation by moving down the
-column marked Electromagnetic Energy until it intersects
-the horizontal row labeled Chemical Energy. There we see
-photosynthesis listed in the block. The next conversion is
-from chemical energy to thermal energy via combustion.
-<span class="pb" id="Page_8">8</span>
-We trace this by moving down the Chemical Energy column
-to the Thermal Energy row; combustion is listed in the appropriate
-block. The third and final conversion takes place
-when thermal energy is transformed into mechanical energy
-via the internal combustion engine.</p>
-<p>By the repeated use of the Energy Conversion Matrix in
-this way, we can chart any energy transformation.</p>
-<h4>Problem <span class="larger">1</span></h4>
-<blockquote>
-<p>Continue the automobile example by going through
-the matrix twice more showing how mechanical
-energy is converted into stored chemical energy
-in the car&rsquo;s battery.</p>
-</blockquote>
-<h4>Problem <span class="larger">2</span></h4>
-<blockquote>
-<p>If 1 gram of gasoline (about a tablespoonful) yields
-48,000 joules of thermal energy when burned with
-air, how fast can it make a 1000 kilogram car go?
-Assume the car starts from rest and its engine is
-25% efficient.</p>
-<p>Answers to problems are on <a href="#Page_34">page 34</a>.</p>
-</blockquote>
-<h2 id="c3"><span class="small">LAWS GOVERNING ENERGY CONVERSION</span></h2>
-<h3>The Big Picture: Thermodynamics</h3>
-<p>To the best of our knowledge, energy and mass are always
-conserved together in any transformation. This summary
-of experience has been made into a keystone of science:
-the Law of Conservation of Energy and Mass. It
-states that the total amount of mass and energy cannot be
-altered. This law applies to everything we do, from driving
-a nail to launching a space probe. While the conscience of
-the scientist insists that he continually recheck the truth of
-this law, it remains a bulwark of science.</p>
-<p>The Law of Conservation of Energy and Mass is also
-called the First Law of Thermodynamics. It is related to
-the Second Law of Thermodynamics, which also governs energy
-transformations. The Second Law says, in effect, that
-some energy will unavoidably be lost in all heat engines.
-The first two laws of thermodynamics have been paraphrased
-as (1) You can&rsquo;t win; (2) You can&rsquo;t even break even.
-Let us look at them further.</p>
-<div class="pb" id="Page_9">9</div>
-<h3>You Can&rsquo;t Win</h3>
-<p>We used to think that energy and mass were conserved
-independently, and for many practical purposes we still
-consider them so conserved. But Einstein united the two
-with the famous equation</p>
-<div class="verse">
-<p class="lc">E = mc&sup2;</p>
-</div>
-<div class="verse">
-<p class="t0">where</p>
-<p class="t">E = energy (in joules)</p>
-<p class="t">m = mass (in kilograms)</p>
-<p class="t">c = speed of light</p>
-<p class="t3">(300,000,000 meters per second)</p>
-</div>
-<p>Notice the resemblance to the kinetic energy equation shown
-earlier. Energy cannot appear without the disappearance of
-mass. When energy is locked up in a fuel, it is stored as
-mass. In the gasoline combustion problem, 1 gram of gasoline
-was burned with air to give 48,000 joules of energy.
-Einstein&rsquo;s equation says that in this case mass disappeared
-in the amount</p>
-<div class="verse">
-<p class="lc">m = E/c&sup2; = (4.8 &times; 10&#8308;)/(9 &times; 10&sup1;&#8310;) = 5.3 &times; 10&#8315;&sup1;&sup3; kilogram</p>
-<p class="t2">(half a billionth of a gram)</p>
-</div>
-<p>But, when an H-bomb is exploded, grams and even kilograms
-of mass are converted to energy.</p>
-<p>In direct conversion processes we do not need to worry
-about these mass changes, but at each point we must make
-sure that all energy is accounted for. For example, in outer
-space all energy released from fuels (even food) must ultimately
-be radiated away to empty Space. Otherwise the vehicle
-temperature will keep rising until the Spaceship melts.</p>
-<h3>You Can&rsquo;t Even Break Even</h3>
-<p>Any engineer is annoyed by having to throw energy away.
-Why is energy ever wasted? The Second Law of Thermodynamics
-guides us here. Experience has shown that heat cannot
-be transformed into another form of energy with 100%
-efficiency. We can&rsquo;t explain Nature&rsquo;s idiosyncracies, but we
-have to live with them. So, we accept the fact that every engine
-that starts out with heat must ultimately waste some of
-that energy (<a href="#fig3">Figure 3</a>).</p>
-<div class="pb" id="Page_10">10</div>
-<div class="img" id="fig3">
-<img src="images/p05.jpg" alt="" width="600" height="688" />
-<p class="pcap"><b>Figure 3</b> <i>A typical heat engine
-showing heat input, useful power
-output, and the unavoidable waste
-heat that must be rejected to the
-environment. A pressure-volume
-diagram is shown underneath for a
-closed gas-turbine cycle. Circled
-numbers correspond. The energy
-produced is represented by the
-shaded area. Similar diagrams can
-be made for all heat engines as an
-aid in studying their performance.</i></p>
-</div>
-<dl class="undent pcap"><dt>A TYPICAL HEAT ENGINE</dt>
-<dd>HEAT IN</dd>
-<dd>HEAT SOURCE</dd>
-<dd class="t">REACTOR, BOILER</dd>
-<dd>ELECTRICITY OUT</dd>
-<dd>ENERGY CONVERTER</dd>
-<dd>PUMP</dd>
-<dd>FLUID PIPE</dd>
-<dd>RADIATOR</dd>
-<dd>WASTE HEAT OUT</dd>
-<dt>PRESSURE-VOLUME DIAGRAM</dt>
-<dd>HEAT IN</dd>
-<dd>ENERGY OUT</dd>
-<dd>GAS PRESSURE</dd>
-<dd>WASTE HEAT OUT</dd>
-<dd>GAS VOLUME</dd></dl>
-<p>Direct conversion devices are no exception. Consequently,
-every thermoelectric element or thermionic converter will
-have to provide for the disposition of waste heat. The designer
-will try, however, to make the engine efficiency high
-so that the waste heat will be small. <a href="#fig4">Figure 4</a> shows the
-extensive waste heat radiator on a SNAP 50 power plant
-planned for deep space missions.</p>
-<div class="img" id="fig4">
-<img src="images/p05a.jpg" alt="" width="800" height="478" />
-<p class="pcap"><b>Figure 4</b> <i>Model of SNAP 50 power plant planned
-for deep space missions showing extensive waste
-heat radiator. The system will provide 300 to
-1000 kilowatts of electrical power.</i></p>
-</div>
-<div class="pb" id="Page_11">11</div>
-<h3>Carnot Efficiency</h3>
-<p>In 1824 Sadi Carnot, a young French engineer, conceived
-of an idealized heat engine. This ideal engine had an efficiency
-given by</p>
-<div class="verse">
-<p class="lc">e = 1 - T<sub>c</sub>/T<sub>h</sub> = (T<sub>h</sub> - T<sub>c</sub>)/T<sub>h</sub></p>
-</div>
-<div class="verse">
-<p class="t0">where</p>
-<p class="t">e = the so-called Carnot efficiency (no units)</p>
-<p class="t">T<sub>c</sub> = the temperature of the waste heat reservoir (in degrees Kelvin, &deg;K<a class="fn" id="fr_4" href="#fn_4">[4]</a>)</p>
-<p class="t">T<sub>h</sub> = the temperature of the heat source (in &deg;K)</p>
-</div>
-<p>Unhappily, T<sub>c</sub> cannot be made zero (and e therefore made
-equal to 1, which is 100% efficiency). Physicists have shown
-absolute zero to be unattainable, although they have approached
-to within a hundredth of a degree in the laboratory.</p>
-<p>Waste heat, since it must be rejected to the surrounding
-atmosphere, outer space, or water (rivers, the ocean, etc.),
-must be rejected at T<sub>c</sub> greater than 300&deg;K. The reason for
-this is that these physical reservoirs have average temperatures
-around 300&deg;K (about 80&deg;F) themselves. The fact
-that T<sub>c</sub> must be 300&deg;K or more is a basic limitation on the
-Carnot efficiency. The loss in efficiency with increased T<sub>c</sub>
-explains why a jet plane has a harder job taking off on a hot
-day.</p>
-<p>One way to improve the Carnot efficiency, which is the
-maximum efficiency for any heat engine, is to raise T<sub>h</sub> as
-high as possible without melting the engine. For a coal-fired
-electrical power plant, T<sub>h</sub> = 600&deg;K and T<sub>c</sub> = 300&deg;K, so
-that</p>
-<p class="center">e = 1 - 300/600 = 0.5 = 50%</p>
-<p>The actual efficiency is somewhat less than this ideal
-value because some power is diverted to pumps and other
-<span class="pb" id="Page_12">12</span>
-equipment and to unavoidable heat losses. Later on, we
-shall see that magnetohydrodynamic (MHD) generators hold
-prospects for increasing T<sub>h</sub> by hundreds of degrees.</p>
-<p>Everything that has been said about the Second Law of
-Thermodynamics (You can&rsquo;t even break even) applies to
-heat engines, where we begin with thermal energy. Suppose
-instead that we start with kinetic or chemical energy and
-convert it into electricity without turning it into heat first.
-We can then escape the Carnot efficiency strait jacket.
-Chemical batteries perform this trick. So do fuel cells,
-solar cells, and many other direct conversion devices we
-shall discuss. Thus, we circumvent the Carnot efficiency
-limitation by using processes to which it does not apply.</p>
-<h4>Problem <span class="larger">3</span></h4>
-<blockquote>
-<p>Some space power plants contemplate using the
-space cabin heat (T<sub>h</sub> = 300&deg;K) to drive a heat engine
-which rejects its waste heat to the liquid-hydrogen
-rocket fuel stored at T<sub>c</sub> = 20&deg;K. What
-would be the Carnot efficiency of this engine?</p>
-</blockquote>
-<h2 id="c4"><span class="small">THERMOELECTRICITY</span></h2>
-<h3>After 140 Years: Seebeck Makes Good</h3>
-<p>The oldest direct conversion heat engine is the thermocouple.
-Take two different materials (typically, two dissimilar
-metal wires), join them, and heat the junction. A
-voltage, or electromotive force, can be measured across
-the unheated terminals. T. J. Seebeck first noticed this effect
-in 1821 in his laboratory in Berlin, but, because of a
-mistaken interpretation of what was involved, he did not
-seek any practical application for it. Only recently has any
-real progress been made in using his discovery for power
-production. To use the analogy of A. F. Joffe, the Russian
-pioneer in this field, thermoelectricity lay undisturbed for
-over a hundred years like Sleeping Beauty. The Prince that
-awoke her was the semiconductor.</p>
-<p>As long as inefficient metal wires were used, textbook
-writers were correct in asserting that thermoelectricity
-could never be used for power production. The secret of
-<span class="pb" id="Page_13">13</span>
-practical thermoelectricity is therefore the creation of
-better thermoelectric materials. (Creation is the right word
-since the best materials for the purpose do not exist in
-nature.) To perform this alchemy, we first have to understand
-the Seebeck effect.</p>
-<h3>Electrons and Holes</h3>
-<p>Let&rsquo;s examine the latticework of atoms that make up any
-solid material. In electrical insulators all the atoms&rsquo; outer
-electrons<a class="fn" id="fr_5" href="#fn_5">[5]</a> are held tightly by valence bonds to the neighboring
-atoms. In contrast, any metal has many relatively
-loose electrons which can wander freely through its latticework.
-This is what makes metals good conductors.</p>
-<h3>THERMOELECTRICITY</h3>
-<div class="img" id="fig5">
-<img src="images/p06.jpg" alt="" width="579" height="800" />
-<p class="pcap"><b>Figure 5</b> <i>Thermoelectric
-couple made from p- and
-n-type semiconductors.
-The impurity atoms (I) are different
-in each leg and contribute
-an excess or deficiency of
-valence electrons. Heat drives
-both holes and electrons toward
-the cold junction.</i></p>
-</div>
-<dl class="undent pcap"><dd>T<sub>c</sub> WASTE HEAT OUT</dd>
-<dd>ELECTRONS</dd>
-<dd>LOAD</dd>
-<dd>COLD JUNCTION</dd>
-<dd>HOLES</dd>
-<dd>ELECTRONS</dd>
-<dd><i>p</i> SEMICONDUCTOR</dd>
-<dd><i>n</i> SEMICONDUCTOR</dd>
-<dd>HOT JUNCTION</dd>
-<dd>T<sub>h</sub> HEAT IN</dd>
-<dt>Simplified Sketch of Atomic Lattice</dt>
-<dd>HOLE</dd>
-<dd>ELECTRON</dd>
-<dd>VALENCE BONDS</dd>
-<dd>SEMICONDUCTOR LATTICES</dd>
-<dd>I = Impurity atom</dd></dl>
-<p><a href="#fig5">Figure 5</a> suggests the latticework of a <i>semiconductor</i>. It
-is called a semiconductor because its conductivity falls far
-short of that of the metals. The few electrons available for
-carrying electricity are supplied by the deliberately introduced
-<span class="pb" id="Page_14">14</span>
-impurity atoms, which have more than enough electrons
-to satisfy the valence-bond requirements of the neighboring
-atoms. Without the impurities, we would have an
-insulator. With them, we have an <i>n</i>-type semiconductor.
-The <i>n</i> is for the extra <i>negative</i> electrons.</p>
-<p>A <i>p</i>- or <i>positive</i>-type semiconductor is also included in
-<a href="#fig5">Figure 5</a>. Here the impurity atom does not have enough
-valence electrons to satisfy the valence-bond needs of the
-surrounding lattice atoms. The lattice has been short-changed
-and is, in effect, full of <i>positive holes</i>. Strangely
-enough, these holes can wander through the material just
-like positive charges.</p>
-<p>The electron-hole model does not have the precision the
-physicist likes, but it helps us to visualize semiconductor
-behavior.</p>
-<p>The Seebeck effect is demonstrated when pieces of <i>p</i>- and
-<i>n</i>-type material are joined as shown in <a href="#fig5">Figure 5</a>. Heat at
-the hot junction drives the loose electrons and holes toward
-the cold junction. Think of the holes and electrons as gases
-being driven through the latticework by the temperature
-difference. A positive and a negative terminal are thus produced,
-giving us a source of power. The larger the temperature
-difference, the bigger the voltage difference. Note
-that just one thermocouple <i>leg</i> can produce a voltage across
-its length, but <i>couples</i> made from <i>p</i> and <i>n</i> legs are superior.</p>
-<h3>Practical Thermoelectric Power Generators</h3>
-<p>The first nuclear-heated thermoelectric generator was
-built in 1954 by the Atomic Energy Commission&rsquo;s Mound
-Laboratory in Miamisburg, Ohio. It used metal-wire thermocouples.
-In contrast, the SNAP 3 series thermocouples
-shown in <a href="#fig1">Figure 1</a> are thick lead telluride (PbTe) semiconductor
-cylinders about two inches long. In contrast to the
-thermocouple wires&rsquo; efficiency of less than 1%, SNAP 3
-series generators have overall efficiencies exceeding 5%.
-This value is still low compared to the 35-40% obtained in
-a modern steam power plant, but SNAP 3 generators can
-operate unattended in remote localities where steam plants
-would be totally unacceptable.</p>
-<p>Look again at the thermoelements in <a href="#fig1">Figure 1</a> and the
-schematic, <a href="#fig5">Figure 5</a>. Underlying the apparent simplicity of
-<span class="pb" id="Page_15">15</span>
-the thermoelectric generator are extensive development efforts.
-The <a href="#fig1">Figure 1</a> thermoelectric couple, for example,
-shows the fruits of thousands of experimental brazing tests.
-It turns out to be uncommonly difficult to fasten thermoelectric
-elements to the so-called <i>hot shoe</i> (metal plate) at
-the bottom. The joint has to be strong, must withstand high
-temperatures, and must have low electrical resistance. We
-see also that the elements are encased in mica sleeves to
-prevent chemical disturbance of the delicate balance of impurities
-in the semiconductor by the surrounding gases. A
-further complication is the extreme fragility of the elements,
-and this has yet to be overcome.</p>
-<p>Nuclear thermoelectric generators that provide small
-amounts of electrical power have already been launched into
-space aboard Department of Defense satellites (<a href="#fig12">Figure 12</a>),
-installed on land stations in both polar regions, and placed
-under the ocean.<a class="fn" id="fr_6" href="#fn_6">[6]</a> Propane-fueled thermoelectric generators,
-such as shown in <a href="#fig6">Figure 6</a>, are now on the market for
-use in camping equipment, in ocean buoys, and in remote
-spots where only a few watts of electricity are needed. The
-Russians have long manufactured a kerosene lamp with
-thermoelements placed in its stack for generating power in
-wilderness areas.</p>
-<div class="img" id="fig6">
-<img src="images/p07.jpg" alt="" width="800" height="591" />
-<p class="pcap"><b>Figure 6</b> <b>GENERAL PURPOSE GENERATOR</b>
-<br /><i>Commercially
-available thermoelectric
-generators using propane
-fuel can provide more than
-enough electrical power to
-operate a portable TV set.</i>
-<span class="jr">Courtesy Minnesota Mining &amp; Manufacturing Company.</span></p>
-</div>
-<p>For the present the role of thermoelectric power appears
-to be one of special uses such as those just mentioned.
-When higher efficiencies are attained, thermoelectric power
-may, one day, supplant dynamic conversion equipment in
-certain low-power applications regardless of location.</p>
-<div class="pb" id="Page_16">16</div>
-<h2 id="c5"><span class="small">THERMIONIC CONVERSION</span></h2>
-<h3>&ldquo;Boiling&rdquo; Electrons Out of Metals</h3>
-<p>Like the thermoelectric element, the thermionic converter
-is a heat engine. In its simplest form it consists of two
-closely spaced metallic plates and resembles the diode radio
-tube. Whereas thermoelectric elements depend on heat to
-drive electrons and holes through semiconductors to an external
-electricity-using device or <i>load</i>, the salient feature
-of the thermionic diode is <i>thermionic
-emission</i>,<a class="fn" id="fr_7" href="#fn_7">[7]</a> or, simply,
-the boiling-off of electrons from a hot metal surface.
-The thermionic converter shown in <a href="#fig7">Figure 7</a> powers a small
-motor when heated by a torch.</p>
-<p>Metals, as we have already seen, have
-an abundance of loosely bound conduction
-electrons roaming the atomic latticework.
-These electrons are easily moved by
-electric fields while within the metal; but
-it takes considerably more energy to boil
-them out of the metal into free space.
-Work has to be done against the electric
-fields set up by the surface layer of
-atoms, which have unattached valence
-bonds on the side facing empty space.</p>
-<p>The energy required to completely detach
-an electron from the surface is called
-the metal&rsquo;s <i>work function</i>. In the case of
-tungsten, for example, the work function
-is about 4.5 electron volts<a class="fn" id="fr_8" href="#fn_8">[8]</a> of energy.</p>
-<div class="img" id="fig7">
-<img src="images/p08.jpg" alt="" width="503" height="600" />
-<p class="pcap"><b>Figure 7</b> <i>Vacuum type thermionic
-converter in operation.</i>
-<span class="jr">Courtesy General Electric Company.</span></p>
-</div>
-<p>As we raise the temperature of a metal, the conduction
-electrons in the metal also get hotter and move with greater
-velocity. We may think of some of the electrons in a metal
-as forming a kind of <i>electron gas</i>. Some electrons will gain
-such high speeds that they can escape the metal surface.
-<span class="pb" id="Page_17">17</span>
-This happens when their kinetic energy exceeds the metal&rsquo;s
-work function.</p>
-<p>Now that we have found a way to force electrons out of
-the metal, we would like to make them do useful electrical
-work. To do this we have to push the electrons across the
-gap between the plates as well as create a voltage difference
-to go with the hoped-for current flow.</p>
-<h3>Reducing the Space Charge</h3>
-<p>The emitted or boiled-off electrons between the converter
-plates (<a href="#fig8">Figure 8</a>) form a cloud of negative charges that
-will repel subsequently emitted electrons back to the emitter
-plate unless counteraction is taken. To circumvent
-these <i>space charge</i> effects, we fill the space between the
-plates with a gas containing positively charged particles.
-These mix with the electrons and neutralize their charge.
-The mixture of positively and negatively charged particles
-is called a <i>plasma</i>.</p>
-<p>The presence of the plasma makes the gas a good conductor.
-The emitted electrons can now move easily across
-it to the collector where, to continue the gas analogy, they
-condense on the cooler surface.</p>
-<div class="img" id="fig8">
-<img src="images/p08a.jpg" alt="" width="800" height="495" />
-<p class="pcap"><b>Figure 8 THERMIONIC CONVERSION</b>
-<br /><i>Thermionic converters may be flat-plate
-types or cylindrical types. The cylindrical
-converter (a) is an experimental type for ultimate
-use in nuclear reactors.</i>
-<span class="jr">Courtesy Los Alamos Scientific Laboratory.</span></p>
-</div>
-<dl class="undent pcap"><dt>a</dt>
-<dd>INSULATOR</dd>
-<dd>COOLED COLLECTOR</dd>
-<dd>INCANDESCENT URANIUM</dd>
-<dd>FUEL ELEMENT</dd>
-<dd>CESIUM PLASMA</dd>
-<dd>CIRCULATING COOLANT</dd>
-<dd>VACUUM INSULATOR</dd>
-<dd>CESIUM POOL</dd>
-<dt>b</dt>
-<dd>WASTE HEAT OUT</dd>
-<dd>LOAD</dd>
-<dd>ELECTRONS</dd>
-<dd>LOW WORK FUNCTION COLLECTOR</dd>
-<dd>T<sub>c</sub></dd>
-<dd>CESIUM ION</dd>
-<dd>PLASMA FILLED GAP</dd>
-<dd>BOILED OFF ELECTRONS</dd>
-<dd>HIGH WORK FUNCTION EMITTER</dd>
-<dd>T<sub>c</sub></dd>
-<dd>HEAT IN</dd></dl>
-<div class="pb" id="Page_18">18</div>
-<h3>Result: A Plasma Thermocouple</h3>
-<p>Unless a voltage difference exists across the plates, no
-external work can be done. In the thermocouple the voltage
-difference was caused by the different electrical properties
-of the <i>p</i> and <i>n</i> semiconductors. Both the emitter and collector
-in the thermionic converter are good metallic conductors
-rather than semiconductors, so a different tack must
-be taken.</p>
-<p>The key is the use of an emitter and a collector with different
-work functions. If it takes 4.5 electron volts to force
-an electron from a tungsten surface and if it regains only
-3.5 electron volts when it condenses on a collector with a
-lower work function, then a voltage drop of 1 volt exists between
-the emitter and collector.</p>
-<p>To summarize, then, the thermionic emission of electrons
-creates the potentiality of current flow. The difference
-in work functions makes the thermionic converter a
-power producer.</p>
-<p>There is an interesting comparison that helps describe
-this phenomenon. Consider the emitter to be the ocean surface
-and the collector a mountain lake. The atmospheric
-heat engine vaporizes ocean water and carries it to the
-cooler mountain elevations, where it condenses as rain
-which collects in lakes. The lake water as it runs back
-toward sea level then can be made to drive a hydroelectric
-plant with the gravitational energy it has gained in the
-transit. The thermionic converter is similar in behavior:
-hot emitter (corresponding to the sun-heated ocean); cooler
-collector (lake); electron gas (water); different electrical
-voltages (gravity). Without gravity the river would not flow,
-and the production of electricity would be impossible.</p>
-<h3>Thermionic Power in Outer Space</h3>
-<p>Thermionic converters for use in outer space may be
-heated by the sun, by decaying radioisotopes, or by a fission
-reactor. Thermionic converters can also be made into
-concentric cylindrical shells (<a href="#fig8">Figure 8</a>a) and wrapped
-around the uranium fuel elements in nuclear reactors. The
-waste heat in this case would be carried out of the reactor
-to a separate radiator<a class="fn" id="fr_9" href="#fn_9">[9]</a> by a stream of liquid metal. Since
-<span class="pb" id="Page_19">19</span>
-thermionic converters can operate at much higher temperatures
-than thermoelectric couples or dynamic power plants,
-the radiator temperature, T<sub>c</sub>, will also be higher. Consequently,
-space power plants using thermionic converters
-will have small radiators. Once thermionic converters are
-developed which have high reliability and long life, they will
-provide the basis for a new series of lighter, more efficient
-space power plants.</p>
-<h2 id="c6"><span class="small">MAGNETOHYDRODYNAMIC CONVERSION</span></h2>
-<h3>Big Word, Simple Concept</h3>
-<p>Magnetohydrodynamic (MHD) conversion is very unlike
-thermoelectric or thermionic conversion. The MHD generators
-use high-velocity electrically conducting gases to
-produce power and are generically closer to dynamic conversion
-concepts. The only concept they carry forward from
-the preceding conversion ideas is that of the <i>plasma</i>, the
-electrically conducting gas. Yet they are commonly classified
-as <i>direct</i> because they replace the rotating turbogenerator
-of the dynamic systems with a stationary pipe or
-<i>duct</i>.</p>
-<div class="img" id="fig9">
-<img src="images/p09.jpg" alt="" width="1200" height="533" />
-<p class="pcap"><b>Figure 9</b> <i>In the MHD duct (a), the electrons in the hot plasma move
-to the right under influence of force F in the magnetic field B. The
-electrons collected by the right-hand side of the duct are carried to the
-load. In a wire in the armature of a conventional generator (b) the
-electrons are forced to the right by the magnetic field.</i></p>
-</div>
-<dl class="undent pcap"><dt>a</dt>
-<dd>MHD Duct</dd>
-<dd>HOT PLASMA IN</dd>
-<dd>COOL GAS OUT TO RADIATOR</dd>
-<dd>Magnetic Field</dd>
-<dd>LOAD</dd>
-<dd>ELECTRONS</dd>
-<dt>b</dt>
-<dd>CONVENTIONAL GENERATOR</dd>
-<dd>SHAFT</dd>
-<dd>LOAD</dd>
-<dd>Magnetic Field</dd>
-<dd>ARMATURE WIRE</dd>
-<dd>ELECTRONS</dd></dl>
-<div class="pb" id="Page_20">20</div>
-<p>In the conventional dynamic generator, an electromotive
-force is created in a wire that cuts through magnetic lines
-of force, as shown in <a href="#fig9">Figure 9</a>b. It may be helpful to visualize
-the conduction electrons as leaving one end of the wire
-and moving to the other under the influence of the magnetic
-field.</p>
-<p>The force on the electrons in the wire is given by</p>
-<div class="verse">
-<p class="lc">F = qvB</p>
-</div>
-<div class="verse">
-<p class="t0">where</p>
-<p class="t">F = the force (in newtons<a class="fn" id="fr_10" href="#fn_10">[10]</a>)</p>
-<p class="t">q = the charge on the electron (1.6 &times; 10&#8315;&sup1;&#8313; coulomb)</p>
-<p class="t">v = the wire&rsquo;s velocity (in meters per second)</p>
-<p class="t">B = the magnetic field strength (in webers per square meter<a class="fn" href="#fn_10">[10]</a>)</p>
-</div>
-<p>The surge of electrons along the length of the wire sets
-up a voltage difference across the ends of the wire. A generator
-uses this difference to convert the kinetic energy of
-the moving wire or armature into electrical energy. The
-wire is kept spinning by the shaft which is connected to a
-turbine driven by steam or water.</p>
-<p>Let us try to eliminate the moving part, the generator
-armature. What we need is a moving conductor that has no
-shaft, no bearings, no wearing parts. The substance that
-meets these requirements is the plasma. Examine <a href="#fig9">Figure 9</a>a.
-The MHD generator substitutes a moving, conducting gas
-for the wires. Under the influence of an external magnetic
-field, the conduction electrons move through the plasma to
-one side of the duct which carries electrical power away to
-the load.</p>
-<p>The MHD generator gets its energy from an expanding,
-hot gas; but, unlike the turbogenerator, the heat engine and
-generator are united in the static duct. The gradual widening
-of the duct shown in <a href="#fig9">Figure 9</a>a reflects the lower pressure,
-cooler plasma at the duct&rsquo;s end. Some of the plasma&rsquo;s
-thermal energy content has been tapped off by the duct&rsquo;s
-electrodes as electrical power.</p>
-<div class="pb" id="Page_21">21</div>
-<h3>The Fourth State of Matter</h3>
-<p>Plasma can be created by temperatures over 2000&deg;K. At
-this temperature many high-velocity gas atoms collide with
-enough energy to knock electrons off each other and thus
-become ionized. The material thus created, shown as a
-glowing gas in <a href="#fig10">Figure 10</a>, does not behave consistently as
-any of the three familiar states of matter: solid, liquid, or
-gas. Plasma has been called a <i>fourth state of matter</i>. Since
-we have difficulty in containing such high temperatures on
-earth, we adopt the strategy of <i>seeding</i>. In this technique
-gases that are ordinarily difficult to ionize, like helium,
-are made conducting by adding a fraction of a percent of an
-alkali metal such as potassium. Alkali metal atoms have
-loosely bound outer electrons and quickly become ionized
-at temperatures well below 2000&deg;K.</p>
-<div class="img" id="fig10">
-<img src="images/p10.jpg" alt="" width="800" height="542" />
-<p class="pcap"><b>Figure 10</b> <i>Glowing plasma in experimental device at
-General Atomic&rsquo;s John Jay Hopkins Laboratory, San
-Diego. T-shaped plasma gun provides data for research
-in thermonuclear fusion.</i>
-<span class="jr">Courtesy Texas Atomic Energy Research Foundation.</span></p>
-</div>
-<p>A helium-potassium mixture is a good enough conductor
-for use in an MHD generator. In this plasma the electrons
-move rapidly under the influence of the applied fields,
-though not as well as in metals. The positive ions move in
-the opposite direction from the electrons, but the electrons
-are much lighter and move thousands of times faster thus
-carrying the bulk of the electrical current.</p>
-<div class="pb" id="Page_22">22</div>
-<h3>MHD Power Prospects</h3>
-<p>The MHD duct is not a complete power plant in itself because,
-after leaving the duct, the stream of gas must be
-compressed, heated, and returned to the duct. Very high
-temperature materials and components must be developed
-for this kind of service. Moreover, while the duct is simple
-in concept, it must operate at very high temperatures in the
-presence of the corrosive alkali metals. This presents us
-with difficult materials problems. When the problems are
-solved, probably within the next decade, MHD power plants
-should be able to provide reliable power with high efficiency.
-They may then serve in large space power plants, and, most
-important, they may provide cheaper electricity for general
-use through their higher temperatures and greater efficiencies.</p>
-<h2 id="c7"><span class="small">CHEMICAL BATTERIES</span></h2>
-<h3>Electricity from the Chemical Bond</h3>
-<p>If you vigorously knead a lemon to free the juices and then
-stick a strip of zinc in one end and a copper strip in the
-other, you can measure a voltage across the strips. Electrons
-will flow through the load without the inconvenience of
-having to supply heat. You have made yourself a chemical
-battery.</p>
-<p>The chemical battery was the first direct conversion device.
-Two hundred years ago it was the scientists&rsquo; only continuous
-source of electricity.</p>
-<p>Since the chemical battery does not need heat for its operation,
-it is logical to ask what makes the current flow.
-Where does the energy come from?</p>
-<p>The battery has no semiconductors, but, like the thermoelectric
-couple and the thermionic diode, it uses dissimilar
-materials for its electrodes. A conducting fluid or solid is
-also present to provide for the passage of current between
-the electrodes. In the example of the lemon, the copper and
-zinc are the dissimilar electrodes, and the lemon juice is
-the conducting fluid or <i>electrolyte</i> that supplies positive and
-negative ions. The battery derives its energy from its complement
-of chemical fuel. The voltage difference arises
-<span class="pb" id="Page_23">23</span>
-because of the different strengths of the chemical bonds.
-The chemical bond is basically an electrostatic one; some
-atoms have stronger electrical affinities than others.</p>
-<h3>Chemical Reactions Used in Batteries and Fuel Cells</h3>
-<p>Consider the following chemical reactions of common
-batteries together with some fuel cell reactions which will
-be discussed further in the next section.</p>
-<dl class="undent"><dt><span class="ss">Battery Reactions</span></dt>
-<dd>Pb + PbO&#8322; + 2H&#8322;SO&#8324; &hArr; 2PbSO&#8324; + 2H&#8322;O</dd>
-<dd>Fe + NiO&#8322; &hArr; FeO + NiO</dd>
-<dd>Zn + AgO + H&#8322;O &hArr; Ag + Zn(OH)&#8322;</dd>
-<dd>Pb + Ag&#8322;O &hArr; PbO + 2Ag</dd>
-<dt><span class="ss">Fuel Cell Reactions</span></dt>
-<dd>2LiH &hArr; 2Li + H&#8322;</dd>
-<dd>2CuBr&#8322; &hArr; 2CuBr + Br&#8322;</dd>
-<dd>2H&#8322; + O&#8322; &hArr; 2H&#8322;O (Bacon cell)</dd>
-<dd>PbI&#8322; &hArr; Pb + I&#8322;</dd></dl>
-<p>In principle all these reactions are the same as those
-going on inside the lemon, although each type of cell produces
-a slightly different voltage because of the varying
-chemical affinities of the atoms and molecules involved.
-There are literally hundreds of materials which can be used
-for electrolytes and electrodes.</p>
-<p>No heat needs to be added as the electrostatic chemical
-bonds are broken and remade in a battery to generate electrical
-power. The chemical reaction energy is transferred
-to the electrical load with almost 100% efficiency. The
-Carnot cycle is no limitation here; only &ldquo;cold&rdquo; electrostatic
-forces are in action. The reactions cannot go on forever,
-however, because the battery supplies the energy converter
-with a very limited supply of fuel. Eventually the
-fuel is consumed and the voltage drops to zero. This deficiency
-is remedied by the fuel cell in which fuel is supplied
-continuously.</p>
-<h3>An Old Standby in Outer Space</h3>
-<p>Almost every satellite and space vehicle has a chemical
-battery aboard. It is not there so much for continuous power
-production but as a rechargeable electrical accumulator or
-reservoir to provide electricity during peak loads. The battery
-is also needed to store energy for use during the periods
-when solar cells are in the earth&rsquo;s shadow and therefore
-inoperative. In this capacity the dependable old battery
-serves the most modern science very well indeed.</p>
-<div class="pb" id="Page_24">24</div>
-<h2 id="c8"><span class="small">THE FUEL CELL: A CONTINUOUSLY FUELED BATTERY</span></h2>
-<h3>Potential Fuels</h3>
-<p>The battery has a very close relative, the fuel cell. Unlike
-the battery the fuel cell has a continuous supply of fuel.</p>
-<div class="img" id="fig11">
-<img src="images/p12.jpg" alt="" width="800" height="559" />
-<p class="pcap"><b>Figure 11</b> <i>This diagram shows how a hydrogen-oxygen fuel cell
-works. The chemical battery works in the same way, except that the
-chemicals are different and are not continuously supplied from outside
-the cell. The water produced by the H-O cell shown can be used for
-drinking on spaceships.</i></p>
-</div>
-<dl class="undent pcap"><dt>ANODE H&#8322; IN</dt>
-<dt>CATHODE O&#8322; IN</dt>
-<dt>ELECTRONS</dt>
-<dt>LOAD</dt>
-<dt>KOH ELECTROLYTE</dt>
-<dt>K&#8314; ION</dt>
-<dt>OH&#8315; ION</dt>
-<dt>NEGATIVE ION FLOW</dt>
-<dt>40H&#8315; + 2H&#8322; &rArr; 4H&#8322;O + 4e</dt>
-<dt>O&#8322; + 2H&#8322;O + 4e &rArr; 40H&#8315;</dt></dl>
-<p>The hydrogen-oxygen cell of <a href="#fig11">Figure 11</a> is typical of all
-fuel cells. It essentially burns hydrogen and oxygen to form
-water. If the hydrogen and oxygen can be supplied continuously
-and the excess water drained off, we can greatly extend
-the life of the battery. The fuel cell accomplishes this.
-Fueled <i>electrical</i> cell would be more descriptive since the
-physical principles are identical with those of the battery.</p>
-<p>Perhaps the most challenging task contemplated for the
-fuel cell is to bring about the consumption of raw or slightly
-processed coal, gas, and oil fuels with atmospheric oxygen.
-If fuel cells can be made to use these abundant fuels, then
-the high natural conversion efficiency of the fuel cells will
-make them economically superior to the lower efficiency
-steam-electric plants now in commercial service.</p>
-<div class="pb" id="Page_25">25</div>
-<p>So far we have dwelt on the fuel cell as a cold energy conversion
-device that is <i>not</i> limited by the Carnot efficiency.
-A variation on this theme is possible. Take a hydrogen
-iodide (HI) cell, and heat the HI to 2000&deg;K. Some of the HI
-molecules will collide at high velocities and dissociate into
-hydrogen and iodine: 2HI = H&#8322; + I&#8322;; the higher the temperature,
-the more the dissociation. By separating the hydrogen
-and iodine gases and returning them for recycling to the
-fuel cell where they are recombined, we have eliminated
-the fuel supply problem and created a <i>regenerative</i> fuel
-cell. We have, however, also reintroduced the heat engine
-and the Carnot cycle efficiency. The thermally regenerative
-fuel cell is a true heat engine using a dissociating gas as
-the working fluid.</p>
-<h3>Scheme for Project Apollo</h3>
-<p>Most of the impetus for developing the fuel cell as a practical
-device comes from the space program. The cell has
-admirable properties for space missions that are less than
-a few months in duration. It is a clean, quiet, vibrationless
-source of energy. Like the battery it has a high electrical
-overload capacity for supplying power peaks and is easily
-controlled. It can even provide potable water for a crew if
-the Bacon H - O cell is used. For short missions where
-large fuel supplies are not needed, it is also among the
-lightest power plants available.</p>
-<p>These compelling advantages have led the National Aeronautics
-and Space Administration to choose the fuel cell for
-some of the first manned space ventures. Project Apollo,
-the manned lunar landing mission, is the most notable example.
-Here the fuel cell will be not only an energy source,
-but also part of the ecological cycle which keeps the crew
-alive.</p>
-<h4>Problem <span class="larger">4</span></h4>
-<blockquote>
-<p>A manned space vehicle requires an average of 2
-electrical kilowatts. A nuclear reactor thermoelectric
-plant having a mass of 1000 kilograms,
-including shielding, can supply this power for
-10,000 hours. The basic fuel cell has a mass of 50
-kilograms and consumes &frac12; kilogram of chemicals
-per hour. The chemical containers weigh 25 kilograms.
-What is the longest mission where the
-total weight of the fuel cell will be less than the
-weight of the nuclear power plant?</p>
-</blockquote>
-<div class="pb" id="Page_26">26</div>
-<h2 id="c9"><span class="small">SOLAR CELLS</span></h2>
-<h3>Photons as Energy Carriers</h3>
-<p>All our fossil fuels, such as coal and oil, owe their existence
-to the solar energy stream that has engulfed the earth
-for billions of years. The power in this stream amounts to
-about 1400 watts per square meter at the earth, nearly
-enough to supply an average home if all the energy were
-converted to electricity. The problem is to get the sun&rsquo;s
-rays to yield up their energy with high efficiency.</p>
-<p>The sun&rsquo;s visible surface has a temperature around
-6000&deg;K. Any object heated to this temperature will radiate
-visible light mostly in the yellow-green portion of the spectrum
-(5500 A<a class="fn" id="fr_11" href="#fn_11">[11]</a>). Our energy conversion device should be
-tuned to this wavelength.</p>
-<p>The energy packets arriving from the sun are called
-photons. They travel, of course, at the speed of light, and
-each carries an amount of energy given by</p>
-<div class="verse">
-<p class="lc">E = hf = hc/&lambda;</p>
-</div>
-<div class="verse">
-<p class="t0">where</p>
-<p class="t">E = energy (in joules)</p>
-<p class="t">h = Planck&rsquo;s constant (6.62 &times; 10&#8315;&sup3;&#8308; joule-second)</p>
-<p class="t">f = the light&rsquo;s frequency (in cycles per second = c/&lambda;)</p>
-<p class="t">c = the velocity of light (300,000,000 meters per second)</p>
-<p class="t">&lambda; = the wavelength (in meters)</p>
-</div>
-<p>Using the fact that an angstrom unit is 10&#8315;&sup1;&#8304; meter, the energy
-of a 5500 A photon could be calculated as</p>
-<div class="verse">
-<p class="lc">E = hf = hc/&lambda; = (6.62 &times; 10&#8315;&sup3;&#8308; &times; 3.00 &times; 10&#8312;)/(5.50 &times; 10&#8315;&#8311;)</p>
-<p class="lc">= 3.61 &times; 10&#8315;&sup1;&#8313; joule = 2.2 electron volts</p>
-</div>
-<p>Comparing this result, 2.2 electron volts, with the energies
-required to cause atomic ionization or molecular dissociation
-<span class="pb" id="Page_27">27</span>
-(an electron volt or so), we see that it is in the
-right range to actuate direct conversion devices based on
-such phenomena.</p>
-<h3>Harnessing the Sun&rsquo;s Energy</h3>
-<p>Historically, the sun&rsquo;s energy has most often been used
-by concentrating it with a lens or mirror and then converting
-it to heat. We could do this and run a heat engine, but a
-more direct avenue is open.</p>
-<p>About a decade ago it was found that the junction between
-<i>p</i> and <i>n</i> semiconductors would generate electricity if illuminated.
-This discovery led to the development of the <i>solar
-cell</i>, a thin, lopsided sandwich of silicon semiconductors.
-As shown in <a href="#fig12">Figure 12</a>, the top semiconductor layer exposed
-to the sun is extremely thin, only 2.5 microns. Solar photons
-can readily penetrate this layer and reach the junction
-separating it from the thick main body of the solar cell.</p>
-<div class="img" id="fig12">
-<img src="images/p13.jpg" alt="" width="1200" height="481" />
-<p class="pcap"><b>Figure 12 THE SOLAR CELL</b>
-<br /><i>The photograph shows the solar cell in use
-on a satellite. The spherical, radioisotope, thermoelectric
-generator at the bottom of the satellite is used to supplement
-the solar cells. In the solar cell, hole-electron pairs
-are created by solar photons in the vicinity of a p-n junction.</i>
-<span class="jr">Courtesy U. S. Air Force and National Aeronautics and Space Administration.</span></p>
-</div>
-<dl class="undent pcap"><dt><i>p</i> SILICON</dt>
-<dt><i>n</i> SILICON</dt>
-<dt>ELECTRON-MOLE PAIRS</dt>
-<dt>JUNCTION</dt>
-<dt>PHOTONS FROM SUN OR RADIOISOTOPE</dt>
-<dt>ELECTRONS</dt>
-<dt>ENERGY OUT</dt></dl>
-<p>Whenever <i>p-</i> and <i>n-</i>type semiconductors are sandwiched
-together a voltage difference is created across the junction.
-The separated holes and electrons in the two semiconductor
-regions establish this electric field across the junction.
-Unfortunately, there are usually no current carriers in the
-immediate vicinity of the junction so that no power is produced.</p>
-<div class="pb" id="Page_28">28</div>
-<p>The absorption of solar photons in the vicinity of the junction
-will create current carriers, as the photons&rsquo; energy is
-transformed into the potential energy of the hole-electron
-pairs. These pairs would quickly recombine and give up
-their newly acquired potential energy if the electric field
-existing across the junction did not whisk them away to an
-external load.</p>
-<p>The solar cell produces electricity when hole-electron
-pairs are formed. Any other phenomenon that creates such
-pairs will also generate electricity. The source of energy
-is irrelevant so long as the current carriers are formed
-near the junction. Thus, particles emitted by radioactive
-atoms can also produce electricity from solar cells, although
-too much bombardment by such particles can damage
-the cell&rsquo;s atomic structure and reduce its output.</p>
-<p>The solar cell is not a heat engine. Yet it loses enough
-energy so that the sun&rsquo;s energy is converted at less than
-15% efficiency. Losses commonly occur because of the recombination
-of the hole-electron pairs before they can produce
-current, the absorption of photons too far from the
-junction, and the reflection of incident photons from the top
-surface of the cell. Despite these losses solar cells are
-now the mainstay of nonpropulsive space power.</p>
-<h2 id="c10"><span class="small">NUCLEAR BATTERIES</span></h2>
-<h3>Energy from Nuclear Particles</h3>
-<p>As we have seen, solar cells are able to convert the kinetic
-energy of charged nuclear particles directly into electricity,
-but a simpler and more straightforward way of doing
-this exists. This involves direct use of the flow of charged
-particles as current.</p>
-<p>The <i>nuclear battery</i> shown in <a href="#fig13">Figure 13</a> performs this
-trick. A central rod is coated with an electron-emitting radioisotope
-(a beta-emitter; say, strontium-90). The high-velocity
-electrons emitted by the radioisotope cross the gap
-between the cylinders and are collected by a simple metallic
-sleeve and sent to the load. Simple, but why don&rsquo;t space
-<span class="pb" id="Page_29">29</span>
-charge effects prevent the electrons
-from crossing the gap as they do in
-the thermionic converter? The answer
-lies in the fact that the nuclear electrons
-have a million times more kinetic
-energy than those boiled off the
-thermionic converter&rsquo;s emitter surface.
-Consequently, they are too powerful
-to be stopped by any space charge
-in the narrow gap.</p>
-<p>Nuclear batteries are simple and
-rugged. They generate only microamperes
-of current at 10,000 to 100,000
-volts.</p>
-<div class="img" id="fig13">
-<img src="images/p14.jpg" alt="" width="486" height="800" />
-<p class="pcap"><b>Figure 13 A NUCLEAR BATTERY</b>
-<br /><i>The nuclear battery
-depends upon the emission of
-charged particles from a surface
-coated with a radioisotope. The
-particles are collected on another
-surface.</i></p>
-</div>
-<dl class="undent pcap"><dt>ENERGY OUT</dt>
-<dt>INSULATOR</dt>
-<dt>LAYER OF BETA-EMITTING RADIOISOTOPE</dt>
-<dt>VACUUM</dt></dl>
-<h3>Double Conversion</h3>
-<p>In the earlier description of the energy conversion matrix,
-we saw that we could go through the energy transformation
-process repeatedly until we obtained the kind of energy
-we wanted. This is exemplified in a type of nuclear
-battery which uses the so-called <i>double conversion</i> approach.
-First, the high-velocity nuclear particles are absorbed
-in a phosphor which emits visible light. The photons
-thus produced are then absorbed in a group of strategically
-placed solar cells, which deliver electrical power to the
-load. Although efficiency is lost at each energy transformation,
-the double conversion technique still ends up with an
-overall efficiency of from 1 to 5%, an acceptable value for
-power supplies in the watt and milliwatt ranges.</p>
-<div class="pb" id="Page_30">30</div>
-<h2 id="c11"><span class="small">ADVANCED CONCEPTS</span></h2>
-<p>Ferroelectric and thermomagnetic conversion are subtle
-concepts which depend upon the gross alteration of a material&rsquo;s
-physical properties by the application of heat. Devices
-employing such concepts are true heat engines. Instead
-of the gaseous and electronic working fluids used in
-the other direct conversion concepts, the ferroelectric and
-thermomagnetic concepts employ patterns of atoms and
-molecules that are actually rearranged periodically by heat.</p>
-<h3>Ferroelectric Conversion</h3>
-<p>Ferroelectric conversion makes use of the peculiar properties
-of <i>dielectric</i><a class="fn" id="fr_12" href="#fn_12">[12]</a> materials. Barium titanate, for example,
-has good dielectric properties at low temperatures,
-but, when its temperature is raised to more than 120&deg;C,
-the properties get worse rapidly. We cannot discuss dielectric
-behavior thoroughly in this booklet; suffice it to say that
-in this process heat is absorbed in a realignment of molecules
-within the barium titanate latticework.</p>
-<p>If we now place a slab of barium titanate between the two
-plates of an electrical condenser and charge the condenser,
-as shown in <a href="#fig14">Figure 14</a>, we have a unique way of converting
-heat into electricity directly. When the barium titanate is
-heated above its <i>Curie point</i><a class="fn" id="fr_13" href="#fn_13">[13]</a> of 120&deg;C, the condenser&rsquo;s
-capacitance is radically reduced as the dielectric constant
-falls. The condenser is forced to discharge and move electrons
-through an external circuit consisting of the load and
-the original source of charge. Useful electrical energy is
-delivered during this step. <a href="#fig14">Figure 14</a> shows the process
-schematically and mathematically. When the dielectric is
-cooled, waste heat is given up by the barium titanate, and
-the cycle is complete.</p>
-<div class="pb" id="Page_31">31</div>
-<div class="img" id="fig14">
-<img src="images/p15.jpg" alt="" width="1000" height="440" />
-<p class="pcap"><b>Figure 14 FERROELECTRIC ENERGY CONVERSION</b>
-<br /><i>The ferroelectric converter is really an electrical capacitor
-whose capacitance is changed by temperature. When heat is
-added, capacitance drops, voltage rises, and the capacitor is made to
-discharge through the load. CYCLE: <b>&#9312;</b> Switch #1 closed, #2 open.
-Condenser charges from battery to charge Q&#8322; at voltage V&#8321; with capacity
-C&#8321;. <b>&#9313;</b>  All switches open. Heat added, capacity changes from
-C&#8321; to C&#8322;, charge remains constant, so voltage changes from V&#8321; to V&#8322;.
-<b>&#9314;</b> Switch #2 closed, #1 open. Condenser discharges through load and
-battery to charge Q&#8321; at voltage V&#8321; with capacity C&#8322;. <b>&#9315;</b> All switches
-open. Heat rejected, capacity changes from C&#8322; to C&#8321;, charge remains
-constant, so voltage changes from V&#8321; to V&#8320;. CYCLE THEN REPEATS.
-Energy supplied from battery each cycle is E&#8321;. Energy delivered to
-load and battery each cycle is E&#8322;. Net energy converted is then E&#8322; - E&#8321;,
-the difference in the shaded areas.</i></p>
-</div>
-<dl class="undent pcap"><dt>(a) CIRCUIT</dt>
-<dd>HEAT IN</dd>
-<dd>BARIUM TITANATE DIELECTRIC</dd>
-<dd>WASTE HEAT OUT</dd>
-<dd>SWITCH #2</dd>
-<dd>LOAD</dd>
-<dd>SWITCH #1</dd>
-<dd>BATTERY</dd>
-<dt>(b) CYCLE DIAGRAM</dt>
-<dd>charge</dd>
-<dd>volts</dd>
-<dd>Q&#8322;, Q&#8321;, E&#8321;, E&#8322;, V&#8320;  V&#8321;  V&#8322;</dd>
-<dd>GENERAL INFORMATION:</dd>
-<dd class="t">C&#8322; &lt; C&#8321;</dd>
-<dd class="t">V = Q/C</dd></dl>
-<h3>Thermomagnetic Conversion</h3>
-<p>The <i>analog</i><a class="fn" id="fr_14" href="#fn_14">[14]</a> of ferroelectricity is ferromagnetism. A
-converter employing similar principles to those in ferroelectricity
-can be made using an electrical <i>inductance</i> with
-a ferromagnetic core. When the temperature of the ferromagnetic
-material is raised above its Curie point, its magnetic
-<i>permeability</i> drops quickly, causing the magnetic field
-to collapse partially. Energy may be delivered to an external
-load during this change. Instead of energy being stored
-in an electrostatic field, it is stored in a magnetic field.</p>
-<div class="pb" id="Page_32">32</div>
-<p>Ferroelectric and thermomagnetic conversion both represent
-a class of energy transformations which involve internal
-molecular or crystalline rearrangements of solids.
-There is no change of phase as in a steam engine, but the
-energy changes are there nevertheless. In thermodynamics
-such internal geometrical changes are called <i>second-order</i>
-transitions, as opposed to the <i>first-order</i> transitions observed
-with heat engines using two-phase working fluids
-like water/steam.</p>
-<h3>On the Frontier</h3>
-<p>Other potential energy conversion schemes are being investigated
-by scientists and engineers. Those listed in the
-Energy Conversion Matrix (<a href="#fig2">Figure 2</a>) only scratch the
-surface.</p>
-<p>In particular, we are just learning how to manipulate
-photons. There are photochemical, photoelectric, and even
-photomechanical transformations. These have hardly been
-tapped.</p>
-<p>Consider the reaction when an electron and its antimatter
-equivalent, the positron, meet. They mutually annihilate
-each other in a burst of energy! This energy will be harnessed
-someday.</p>
-<p>What energy conversion device are we going to use to
-completely convert mass into energy? The energy requirements
-for interstellar exploration are so great that these
-voyages will be impossible unless a new device is found
-that can completely transform mass into energy.</p>
-<p>Then again, we haven&rsquo;t the faintest idea of how to control
-gravitational energy, but we may learn.</p>
-<p>The panorama is endless.</p>
-<h4>Problem <span class="larger">5</span></h4>
-<blockquote>
-<p>A 1,000,000-kilogram spaceship takes off for Alpha
-Centauri, our nearest star, 4.3 light years away.
-If it accelerates to nine-tenths the velocity of light,
-what is its kinetic energy? How much fuel mass
-will have to be completely converted to energy to
-acquire this velocity?</p>
-</blockquote>
-<div class="pb" id="Page_33">33</div>
-<h2 id="c12"><span class="small">SUGGESTED REFERENCES</span></h2>
-<h3>Articles</h3>
-<p class="revint">Fuel Cells, Leonard G. Austin, <i>Scientific American</i>, 201: 72 (October 1959).
-A survey of the different types.</p>
-<p class="revint">Nuclear Power in Outer Space, William R. Corliss, <i>Nucleonics</i>, 18: 58 (August
-1960). A review of all nuclear space power plants.</p>
-<p class="revint">Fuel Cells for Space Vehicles, M. G. Del Duca, <i>Astronautics</i>, 5: 36 (March 1960).</p>
-<p class="revint">Fuel Cells, E. Gorin and H. L. Recht, <i>Chemical Engineering Progress</i>, 55: 51
-(August 1959).</p>
-<p class="revint">Thermionic Converters, Karl G. Hernqvist, <i>Nucleonics</i>, 17: 49 (July 1959).</p>
-<p class="revint">The Revival of Thermoelectricity, Abram F. Joffe, <i>Scientific American</i>, 199: 31
-(November 1958). Excellent historical and technical review.</p>
-<p class="revint">The Photovoltaic Effect and Its Utilization, P. Rappaport, <i>RCA Review</i>, 20: 373
-(September 1959). Recommended for advanced students.</p>
-<p class="revint">The Prospects of MHD Power Generation, Leo Steg and George W. Sutton,
-<i>Astronautics</i>, 5: 22 (August 1960).</p>
-<p class="revint">Conversion of Heat to Electricity by Thermionic Emission, Volney C. Wilson,
-<i>Journal of Applied Physics</i>, 30: 475 (April 1959). Recommended for advanced
-students.</p>
-<p class="revint">Improved Solar Cells Planned for IMP-D, R. D. Hibben, <i>Aviation Week &amp; Space
-Technology</i>, 83: 53 (July 26, 1965).</p>
-<p class="revint">Thin-film Solar Cells Boost Output Ratio, P. J. Klass, <i>Aviation Week &amp; Space
-Technology</i>, 83: 67 (November 29, 1965).</p>
-<h3>Books</h3>
-<p class="revint"><i>Direct Conversion of Heat to Electricity</i>, Joseph Kaye and John A. Welsh,
-John Wiley &amp; Sons, Inc., New York 10016, 1960, 387 pp., $11.50. Recommended
-for advanced students.</p>
-<p class="revint"><i>Selected Papers on New Techniques for Energy Conversion</i>, Sumner N. Levine,
-(Ed.), Dover Publications, Inc., New York 10014, 1961, 444 pp., $3.00. A reprinting
-of many classical papers on direct conversion.</p>
-<p class="revint"><i>Energy Conversion for Space Power</i>, Nathan W. Snyder, (Ed.), Academic Press,
-Inc., New York 10003, 1961, 779 pp., $8.50. A collection of American Rocket
-Society papers.</p>
-<p class="revint"><i>Man and Energy</i>, Alfred Rene Ubbelohde, George Braziller, New York 10016,
-1955, 247 pp., $5.00 (hardback); $1.25 (paperback), from Penguin Books, Inc.,
-Baltimore, Maryland 21211. A popular treatment of energy and power.</p>
-<h3>Motion Pictures</h3>
-<p>The following films are produced by Educational Services, Inc., and are available
-from Modern Learning Aids, A Division of Modern Talking Picture Service,
-Inc., 3 East 54th St., New York 22, New York.</p>
-<div class="verse">
-<p class="t0"><i>Energy and Work</i>, 0311, 29 minutes, $150.</p>
-<p class="t0"><i>Mechanical Energy and Thermal Energy</i>, 0312, 27 minutes, $120.</p>
-<p class="t0"><i>Conservation of Energy</i>, 0313, 27 minutes, $150.</p>
-<p class="t0"><i>Photo-Electric Effect</i>, 0417, 28 minutes, $220.</p>
-</div>
-<div class="pb" id="Page_34">34</div>
-<h2 id="c13"><span class="small">ANSWERS TO PROBLEMS</span></h2>
-<p>First, mechanical energy drives the car&rsquo;s electric
-generator. Second, the electrical energy is
-converted into chemical energy when the battery
-is recharged.</p>
-<hr class="dwide" />
-<p>From the kinetic energy equation we get</p>
-<p class="center">v = &#8730;(2 E/m)</p>
-<p>Since the engine is 25% efficient, the energy available
-to propel the car is 48,000 &times; 0.25 or 12,000
-joules. So</p>
-<p class="center">v = &#8730;(24,000/1,000) = 2&#8730;6 = 4.9 meters per second</p>
-<hr class="dwide" />
-<p class="center">e = (300 - 20)/300 = 14/15 = 0.93 = 93%</p>
-<p>The crossover point, t, in hours is found by equating
-the nuclear power plant mass and that of the
-fuel cell with its associated fuel. The equation is</p>
-<p class="center">1000 = 50 + 25 + &frac12;t
-t = 1850 hours = 77 days</p>
-<hr class="dwide" />
-<p class="center">E = &frac12; mv&sup2; = (10&#8310;(0.9 &times; 3 &times; 10&#8312;)&sup2;)/2 = 3.6 &times; 10&sup2;&sup2; joules</p>
-<p>The ship will use the same amount of energy to
-decelerate at its destination. Note that this calculation
-assumes a perfect efficiency in converting
-the energy of matter annihilation into the kinetic
-energy of the space ship. The mass consumed is</p>
-<p class="center">m = E/c&sup2; = (3.6 &times; 10&sup2;&sup2;)/(9 &times; 10&sup1;&#8310;) = 4.0 &times; 10&#8309; kg</p>
-<p>almost half the spaceship mass.</p>
-<div class="pb" id="Page_35">35</div>
-<h2 id="c14"><span class="small">Footnotes</span></h2>
-<div class="fnblock"><div class="fndef"><a class="fn"  id="fn_1" href="#fr_1">[1]</a>Systems for Nuclear Auxiliary Power.
-</div><div class="fndef"><a class="fn"  id="fn_2" href="#fr_2">[2]</a>Described in this booklet.
-</div><div class="fndef"><a class="fn"  id="fn_3" href="#fr_3">[3]</a>Magnetohydrodynamics.
-</div><div class="fndef"><a class="fn"  id="fn_4" href="#fr_4">[4]</a>The Kelvin temperature scale starts with zero at absolute zero instead of at the freezing point of water. Therefore, &deg;K = &deg;C + 273; &deg;K = &#8309;/&#8329; (&deg;F + 460).
-</div><div class="fndef"><a class="fn"  id="fn_5" href="#fr_5">[5]</a>Termed <i>valence</i> or <i>conduction</i> electrons,
-these are responsible
-for chemical properties, bonds with other atoms, and the conduction
-of electricity.
-</div><div class="fndef"><a class="fn"  id="fn_6" href="#fr_6">[6]</a>See the companion Understanding the Atom booklet, <i>Power from
-Radioisotopes</i>.
-</div><div class="fndef"><a class="fn"  id="fn_7" href="#fr_7">[7]</a>Discovered by Thomas Edison in 1883.
-</div><div class="fndef"><a class="fn"  id="fn_8" href="#fr_8">[8]</a>An electron
-volt is equal to the kinetic energy acquired by an
-electron accelerated through a potential difference of 1 volt. It is
-equal to 1.6 &times; 10&#8315;&sup1;&#8313; joule.
-</div><div class="fndef"><a class="fn"  id="fn_9" href="#fr_9">[9]</a>In outer space, waste heat must be radiated away. The rate at
-which heat is radiated is proportional to the fourth power of T<sub>c</sub>
-(Stefan-Boltzmann law).
-</div><div class="fndef"><a class="fn"  id="fn_10" href="#fr_10">[10]</a>The newton and the weber are mks (meter-kilogram-second) units.
-</div><div class="fndef"><a class="fn"  id="fn_11" href="#fr_11">[11]</a>An angstrom unit (A) is a unit of distance measurement equal
-to 10&#8315;&sup1;&#8304; meter.
-</div><div class="fndef"><a class="fn"  id="fn_12" href="#fr_12">[12]</a>Dielectric materials are nonconductors such as are those used
-between the plates of a condenser to increase its electrical capacity.
-</div><div class="fndef"><a class="fn"  id="fn_13" href="#fr_13">[13]</a>The Curie point is the temperature at which a material&rsquo;s crystalline
-structure radically changes and becomes less orderly.
-</div><div class="fndef"><a class="fn"  id="fn_14" href="#fr_14">[14]</a>Ferroelectricity and ferromagnetism are very similar. The
-equations describing these phenomena are almost identical except
-that capacitance is replaced by its magnetic analog, inductance,
-and so on.
-</div>
-</div>
-<hr class="dwide" />
-<p class="tb">This booklet is one of the &ldquo;Understanding the Atom&rdquo;
-Series. Comments are invited on this booklet and others
-in the series; please send them to the Division of Technical
-Information, U. S. Atomic Energy Commission, Washington,
-D. C. 20545.</p>
-<p>Published as part of the AEC&rsquo;s educational assistance
-program, the series includes these titles:</p>
-<div class="verse">
-<p class="t0"><i>Accelerators</i></p>
-<p class="t0"><i>Animals in Atomic Research</i></p>
-<p class="t0"><i>Atomic Fuel</i></p>
-<p class="t0"><i>Atomic Power Safety</i></p>
-<p class="t0"><i>Atoms at the Science Fair</i></p>
-<p class="t0"><i>Atoms in Agriculture</i></p>
-<p class="t0"><i>Atoms, Nature, and Man</i></p>
-<p class="t0"><i>Careers in Atomic Energy</i></p>
-<p class="t0"><i>Computers</i></p>
-<p class="t0"><i>Controlled Nuclear Fusion</i></p>
-<p class="t0"><i>Cryogenics, The Uncommon Cold</i></p>
-<p class="t0"><i>Direct Conversion of Energy</i></p>
-<p class="t0"><i>Fallout From Nuclear Tests</i></p>
-<p class="t0"><i>Food Preservation by Irradiation</i></p>
-<p class="t0"><i>Genetic Effects of Radiation</i></p>
-<p class="t0"><i>Index to the UAS Series</i></p>
-<p class="t0"><i>Lasers</i></p>
-<p class="t0"><i>Microstructure of Matter</i></p>
-<p class="t0"><i>Neutron Activation Analysis</i></p>
-<p class="t0"><i>Nondestructive Testing</i></p>
-<p class="t0"><i>Nuclear Clocks</i></p>
-<p class="t0"><i>Nuclear Energy for Desalting</i></p>
-<p class="t0"><i>Nuclear Power and Merchant Shipping</i></p>
-<p class="t0"><i>Nuclear Power Plants</i></p>
-<p class="t0"><i>Nuclear Propulsion for Space</i></p>
-<p class="t0"><i>Nuclear Reactors</i></p>
-<p class="t0"><i>Nuclear Terms, A Brief Glossary</i></p>
-<p class="t0"><i>Our Atomic World</i></p>
-<p class="t0"><i>Plowshare</i></p>
-<p class="t0"><i>Plutonium</i></p>
-<p class="t0"><i>Power from Radioisotopes</i></p>
-<p class="t0"><i>Power Reactors in Small Packages</i></p>
-<p class="t0"><i>Radioactive Wastes</i></p>
-<p class="t0"><i>Radioisotopes and Life Processes</i></p>
-<p class="t0"><i>Radioisotopes in Industry</i></p>
-<p class="t0"><i>Radioisotopes in Medicine</i></p>
-<p class="t0"><i>Rare Earths</i></p>
-<p class="t0"><i>Reading Resources in Atomic Energy</i></p>
-<p class="t0"><i>Research Reactors</i></p>
-<p class="t0"><i>SNAP, Nuclear Space Reactors</i></p>
-<p class="t0"><i>Sources of Nuclear Fuel</i></p>
-<p class="t0"><i>Synthetic Transuranium Elements</i></p>
-<p class="t0"><i>The Atom and the Ocean</i></p>
-<p class="t0"><i>The Chemistry of the Noble Gases</i></p>
-<p class="t0"><i>The First Reactor</i></p>
-<p class="t0"><i>Whole Body Counters</i></p>
-<p class="t0"><i>Your Body and Radiation</i></p>
-</div>
-<p>A single copy of any one booklet, or of no more than three
-different booklets, may be obtained free by writing to:</p>
-<p class="center"><span class="ss">USAEC, P. O. BOX 62, OAK RIDGE, TENNESSEE&nbsp; 37830</span></p>
-<p>Complete sets of the series are available to school and
-public librarians, and to teachers who can make them
-available for reference or for use by groups. Requests
-should be made on school or library letterheads and indicate
-the proposed use.</p>
-<p>Students and teachers who need other material on specific
-aspects of nuclear science, or references to other
-reading material, may also write to the Oak Ridge address.
-Requests should state the topic of interest exactly, and the
-use intended.</p>
-<p>In all requests, include &ldquo;Zip Code&rdquo; in return address.</p>
-<p class="center smallest">Printed in the United States of America
-<br />USAEC Division of Technical Information Extension, Oak Ridge, Tennessee
-<br />May 1968</p>
-<hr class="dwide" />
-<h2 id="trnotes">Transcriber&rsquo;s Notes</h2>
-<ul>
-<li>Silently corrected a few typos.</li>
-<li>Modified some image references to reflect the pageless flowable eBook format.</li>
-<li>Retained publication information from the printed edition: this eBook is public-domain in the country of publication.</li>
-<li>In the text versions only, text in italics is delimited by _underscores_.</li>
-</ul>
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