PHYSICAL SIGNIFICANCE 
 OF ENTROPY 
 
 OR OF THE SECOND LAW 
 
 BY 
 
 J. F. KLEIN 
 
 Professor of Mechanical Engineering, 
 Lehigh University 
 
 NEW YORK 
 
 D. VAN NOSTRAND COMPANY 
 
 23 MURRAY AND 27 WARREN STREETS 
 
 1910 
 
COPTRIGHT, 1910, 
 BY 
 
 JOSEPH FREDERICK KLEIN 
 
 THE SCIENTIFIC 
 OBERT DRUMMOMO AND COMPANY 
 BROOKLYN, N. Y. 
 
PREFACE 
 
 IN this little book the author has in the main sought to present 
 the interpretation reached by BOLTZMANN and by PLANCK. The 
 writer has drawn most heavily upon PLANCK, for he is at once 
 the clearest expositor of BOLTZMANN and an original and important 
 contributor. Now these two investigators reach the result that 
 entropy of any physical state is the logarithm of the probability 
 of the state, and this probability is identical with the number 
 of "complexions" of the state. This number is the measure of 
 the permutability of certain elements of the state and in this sense 
 entropy is the " measure of the disorder of the motions of a system 
 of mass points." To realize more fully the ultimate nature of 
 entropy, the writer has, in the light of these definitions, interpreted 
 some well-known and much-discussed thermodynamic occurrences 
 and statements. A brief outline of the general procedure followed 
 will be found on p. 3, while a fuller synopsis is of course given 
 in the accompanying table of contents. 
 
 J. F. KLEIN. 
 LEHIGH UNIVERSITY, October, 1910. 
 
 iii 
 
 257815 
 
TABLE OF CONTENTS 
 
 INTRODUCTION 
 
 PAGE 
 
 Purpose, acknowledgments, the two methods of approach and outline of 
 
 treatment. . i 
 
 PART I 
 
 THE DEFINITIONS, GENERAL PRELIMINARIES, DEVELOPMENT, CURRENT 
 AND PRECISE STATEMENTS OF THE MATTERS CONSIDERED 
 
 SECTION A 
 (i) The " state " of a body and its " change of state " 5 
 
 The two points of view; the microscopic and the macroscopic observer; 
 
 the micro-state and macro-state or aggregate 5 
 
 The selected and the rejected micro-states; the use of the hypothesis of 
 
 " elementary chaos " 7 
 
 PLANCK'S fuller description of what constitutes the state of a physical 
 
 system 10 
 
 (2) Further elucidation of the essential prerequisite, " elementary chaos" 
 
 Sundry aspects of haphazard n 
 
 BOLTZMANN'S service to science in this field and his view of what con- 
 stitute the necessary features of haphazard 12 
 
 BURBURY'S simplification of haphazard necessary and his example of 
 
 " elementary chaos " 15 
 
 Haphazard as expressed by a system possessing an extraordinary number 
 of degrees of freedom 17 
 
CONTENTS 
 
 (3) Settled and unsettled states; distinction between final stage of " elemen- 
 tary chaos " and its preceding stages 18 
 
 Each stage has sufficient haphazard; examples and characteristics of the 
 settled and unsettled stages of "elementary chaos"; all micro- 
 states not equally likely; the assumed state of " chaos " does not 
 eliminate adequate haphazard; two anticipatory remarks 19 
 
 SECTION B 
 
 CONCERNING THE APPLICATION OF THE CALCULUS OF PROBABILITIES 
 
 (i) The probability concept, its usefulness in the past, its present 
 
 necessity, and its universality 22 
 
 Popular objection to its use; BOLTZMANN'S justification of this concept; 
 its usefulness in the past and in other fields; some of its good points; 
 the haphazard features necessary for its use 23 
 
 (2) What is meant by probability of a state ? Example 27 
 
 SECTION C 
 
 (i) The existence, definition, measure, properties, relations and scope 
 
 of it 'reversibility and reversibility 29 
 
 Inference from experience; inference from the H-theorem or calculus of 
 probablities; definitions of irreversible and reversible processes; 
 examples of each 30 
 
 (2) Character of process decided by limiting states 32 
 
 Nature's preference for a state; measure of this preference 33 
 
 Entropy both the criterion and the measure of irreversibility 33 
 
 (3) All the irreversible processes stand or fall together 34 
 
 (4) Convenience of the fiction, the reversible processes 35 
 
 Entropy the only universal measure of irreversibility. Outcome of the 
 
 whole study of irreversibility 36 
 
CONTENTS rii 
 
 SECTION D 
 
 PAGB 
 
 (1) The gradual development of the idea that entropy depends on proba- 
 
 bility or number of complexions 37 
 
 Why it is difficult to conceive of entropy. Origin and first definition 
 due to CLAUSIUS; some formulas for it available from the start. Its 
 statistical character early appreciated; lack of precise physical mean- 
 ing; its dependence on probability; number of complexions a synonym 
 for probablity 37 
 
 (2) PLANCK'S formula for the relation between entropy and the number 
 
 of complexions 40 
 
 Certain features of entropy 41 
 
 SECTION E 
 
 Equivalents of change of entropy in more or less general physical terms 
 
 or aspects 41 
 
 Not surprising that its many forms should have been a reproach to the 
 
 second law 41 
 
 General principles for comparing these aspects. Various aspects of 
 growth of entropy from the experiential and from the atomic point 
 of view , 1 42 
 
 SECTION F 
 
 More precise and specific statements of the second law 44 
 
 General arrangement and the principles for comparison 44 
 
 Ten different statements of the law and comments thereon 44 
 
 PART II 
 
 ANALYTICAL EXPRESSIONS FOR A FEW PRIMARY RELATIONS 
 
 Procedure followed 48 
 
 SECTION A 
 
 MaxwelVs law of distribution of molecular velocities 48 
 
 Outline of proof, illustration, and consequences of this law 48 
 
Tiii CONTENTS 
 
 SECTION B 
 
 PAGE 
 
 Simple analytical expression for dependence of entropy on probability 53 
 
 PLANCK'S derivation; illustration, limitations, consequences, features and 
 
 comments 53 
 
 SECTION C 
 
 Determination of a precise, numerical expression for the entropy of 
 
 any physical configuration 56 
 
 BOLTZMANN'S pioneer work, PLANCK'S exposition, and the six main steps. 56 
 
 Step a 
 
 [ probability or number ] 
 Determination of the general expression for the \ 
 
 [ of complexions J 
 
 of a given configuration of a known aggregate state 57 
 
 Step b 
 
 Determination of the general expression for the entropy S of a given con- 
 figuration of a known aggregate state * 63 
 
 Step c 
 
 Special case of (6), namely, expression for the entropy S of the state of 
 
 thermal equilibrium of a monatomic gas 63 
 
 Step d 
 
 Confirmation, by equating this value of S with that found thermodynamic- 
 
 ally and then deriving known results 64 
 
 Step e 
 
 PLANCK'S conversion of the expressions of (b) and (c) into more precise 
 
 ones by finding numerical value of k 66 
 
 Stepf 
 
 Determination of the dimensions of the universal constant k and there- 
 fore also of entropy in general 67 
 
CONTENTS ix 
 
 PART III 
 
 THE PHYSICAL INTERPRETATIONS 
 
 SECTION A 
 Of the simple reversible operations in thermodynamics 
 
 PAGE 
 
 Isometric, isobaric, isothermal, and isentropic change -69 
 
 SECTION B 
 Of the fundamentally irreversible processes 
 
 Heat conduction, work into heat of friction, expansion without work, and 
 
 diffusion of gases 7 2 
 
 SECTION C 
 
 Of negative change of entropy 
 Some of its physical features and necessary accompaniments 78 
 
 SECTION D 
 
 Physical significance of the equivalents for growth of entropy given on 
 
 pp. 42-43 80 
 
 SECTION E 
 
 Physical significance of the more specific statements of second law given 
 
 on pp. 44-47 81 
 
 PART IV 
 
 SUMMARY OF THE CONNECTION BETWEEN PROBABILITY, IRREVERSI- 
 BILITY, ENTROPY, AND THE SECOND LAW 
 
 SECTION A 
 
 (i) Prerequisites and conditions necessary for the application of the 
 theory of probabilities 
 
 (a) Atomic theory; (6) like particles; (c) very numerous particles; (d) 
 
 11 elementary chaos " 83 
 
 (2) Differences in the states of "elementary chaos" 85 
 
 (3) Number of complexions, or probability of a chaotic state... 86 
 
X CONTENTS 
 
 SECTION B 
 
 PA.QB 
 
 Irreversibility 85 
 
 SECTION C 
 Entropy 87 
 
 SECTION D 
 
 The Second Law 
 
 Its basis and best statements; it has no independent significance 88 
 
 PART V 
 
 REACH OR SCOPE OF THE SECOND LAW 
 
 SECTION A 
 
 Its extension to all bodies 
 PLANCK'S presentation; fifteen steps in the proof 91 
 
 SECTION B 
 General conclusion as to entropy changes 98 
 
THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 AND OF THE SECOND LAW 
 
 [There is no difference between change of Entropy and Second Law, when each 
 
 is fully defined.] 
 
 INTRODUCTION 
 
 PURPOSE, ACKNOWLEDGMENTS, THE Two METHODS OF APPROACH 
 AND OUTLINE OF TREATMENT 
 
 THIS article is intended for those students of engineering who 
 already have some elementary knowledge of thermodynamics. 
 It is intended to clear up a difficulty that has beset every earnest 
 beginner of this subject. The difficulty is not one of application 
 to engineering problems, although here too there have been 
 widespread misconceptions, 1 for the expressions developed by 
 CLAUSIUS are simple, have long been known and much used by 
 engineers and physicists. The difficulty is rather as to the 
 ultimate physical meaning of entropy. This term has long been J 
 known as a sort of property of the state of the body, has long been ' 
 surmised to be of essentially a statistical nature, but with it all 
 there was a sense that it was a sort of mathematical fiction, 
 that it was somehow unreal and elusive, so it is no wonder 
 that in certain engineering quarters it was dubbed the "ghostly 
 quantity." 
 
 Now this instinct of the true engineer to understand things 
 
 1 See Entropy, by JAMES SWINBURNE; this author has called attention to 
 necessary corrections and duly emphasized the engineering aspect. 
 
2 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 down to the bottom is worthy of all encouragement and respect. 
 For this reason and because the matter is of prime importance 
 to the technical world, the final .meaning of entropy (i.e., of the 
 Second Law) must be -clarified and realized. Indeed, we may well 
 go beyond this somewhat narrow view and say that this is well 
 worth doing because change of entropy constitutes the driving motive 
 ,in all natural events; it has therefore a reach and a universality 
 which even transcends that of the First Law, or Principle-of the 
 ^Conservation of Energy. 
 
 In striving to present the physical meaning of entropy and of the 
 Second Law, the writer cannot lay claim to any originality; he 
 has simply tried here to put in logical order the somewhat scattered 
 propositions of the leading investigators of this subject and in 
 such a way that the difficulties of apprehension might be minim- 
 ized; in other words, to present the solutions of his own diffi- 
 culties, in the hope that the solutions may be helpful to other 
 students of engineering and thermodynamics. In overcoming these 
 difficulties, the writer owes everything to the books and papers by 
 PLANCK and BOLTZMANN, pre-eminently to PLANCK, who has so 
 clearly and appreciatively interpreted the life work of BOLTZ- 
 MANN. l The writer furthermore wishes to say that he has not 
 hesitated here to quote verbatim from both these investigators 
 and not always so that their own statements can be distinguished 
 from his own. If any part of this presentation is particularly 
 clear and exact the reader will be safe in crediting it to one or 
 the other of these two investigators and expositors, although it 
 would not be right to consider them responsible for everything 
 contained in this little book. 
 
 In considering the proper approach to the matter in hand we 
 must remember that 2 "in physical science there are two more or 
 
 1 BOLTZMANN, Gas Theorie; PLANCK, Thermodynamik, Theorie der Warme- 
 strahlung, and Acht Vorlesungen fiber Theoretische Physik. 
 
 2 Professor W. S. FRANKLIN, The Second Law of Thermodynamics: its basis 
 in Intuition and Common Sense. Pop. Science Monthly, March, 1910. 
 
AND OF THE SECOND LAW 3 
 
 less distinct modes of attack, namely, (a) a mode of attack in 
 which the effort is made to develop conceptions of the physical 
 processes of nature, and (b) a mode of attack in which the attempt 
 is made to correlate phenomena on the basis of sensible things, 
 things that can be seen and measured. In the theory of heat the 
 first mode is represented by the application of the atomic theory 
 to the study of heat phenomena, and the second mode is represented 
 by what is called thermodynamics." In solving the special 
 problem before us, as to the physical meaning of entropy and of 
 the Second Law, our main dependence must be on the first mode 
 of attack. 
 
 The second mode will furnish checks and confirmations of the 
 results developed by the first, or we may say that the combination 
 of the two modes will give the well-established characteristic 
 equations and relations of bodies and their physical elements. 
 
 The whole discussion will now be taken up in a non-mathe- 
 matical way, without the full proof required by a complete presenta- 
 tion, and about in this order: 
 
 (a) The definitions, general preliminaries and current state- 
 ments of the matters considered. 
 
 (6) More or less precise statement of the primary relations 
 and theorems. 
 
 (c) The physical interpretations. 
 
 (d) Summary of the connection between probability, irreversi- 
 bility, entropy and the Second Law. 
 
 (e) Reach or scope of the Second Law. 
 
 On account of the difficulty which every student experience^in 
 realizing the physical nature of entropy we will in the main con- 
 fine our attention here to gases and indeed to their simplest case, 
 the monatomic gas, and will as usual assume that the dimen- 
 sions of an atom or particle are very small in comparison with the 
 average distance between two adjacent particles, that for the atoms 
 approaching collision the distance within which they exert a signifi- 
 cant influence on each other is very small as compared with the 
 
4 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 mean distance between adjacent atoms, and that between collisions 
 the mean length of the particle's path is great in comparison with 
 the average distance between the particles. Later on we will indi- 
 cate in a very general and brief way how the entropy idea may 
 be extended to other states of aggregation and to other than 
 purely thermodynamic phenomena. Mostly, therefore, we will 
 only consider states and processes in which heat phenomena and 
 mechanical occurrences take place. 
 
AND OF THE SECOND LAW 
 
 PART I 
 
 DEFINITIONS, GENERAL PRELIMINARIES, DEVELOPMENT, CURRENT 
 AND PRECISE STATEMENTS OF THE MATTERS CONSIDERED 
 
 (i) The " State " of a Body and its " Change of State " 
 
 As we will make constant use of the terms contained in this 
 heading and as they here represent fundamentally important 
 conceptions, we will seek to make them clear by presenting them 
 in the various forms into which they have been cast by the different 
 investigators, even at the risk of being considered prolix. 
 
 In the Introduction to this article we called attention to the 
 two distinct modes of attacking any physical problem. Now the 
 conception "state of a body" varies with the chosen mode of 
 attack. Of course as both modes are legitimate and lead to 
 correct results, these differences in the conception of "state" 
 can be reconciled and a broader definition reached. We can 
 illustrate these different methods of approach, as PLANCK has 
 done, by assuming two different observers of the state of the body, 
 one called the microscopic-observer and the other the macro- 
 scopic-observer. The former possesses senses so acute and 
 powers so great that he can recognize each individual atom and 
 can measure its motion. For this observer each atom will move 
 exactly according to the elementary laws prescribed for it by 
 General Dynamics. These laws, so far as we know them, also 
 at once permit of exactly the opposite course of each event. Con- 
 sequently there can be here no question of probability, of entropy 
 or of its growth. On the other hand, the "macro-observer," (who 
 perceives the atomic host, say as a homogeneous gas, and conse- 
 
6 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 quently applies to its mechanical and thermal events the laws 
 of thermodynamics) will regard the proc3S3 as a whole to be 
 an irreversible one in accordance with the Second Law. . . . 
 Now a particular change of state cannot at the same time be 
 both reversible and irreversible. But the one observer has a 
 different idea of " change of state" from the other; the micro- 
 observer's conception of " change of state " is different from 
 that of the macro-observer. What then is " change of state?" 
 The state of a physical system can probably not be rigorously 
 denned, otherwise than the conception, as a whole, of all those 
 physical magnitudes whose instantaneous values, under given 
 external conditions, also uniquely determine the sequence of these 
 changing values. 
 
 BOLTZMANN'S statement is much more clear, namely, "The 
 state of a body is determined, (a) by the law of distribution of 
 the particles in space and (b) by the law of distribution of 
 the velocities of the particles; in other words, a body's condition 
 is determined (a) by the number of particles which lie in each 
 elementary realm of the space and (b) by a statement of the 
 number of particles which belong to each elementary velocity 
 group. These elementary realms are all equal and so are the ele- 
 mentary velocity groups equal among themselves. But it is further- 
 more assumed that each elementary realm and each elementary 
 velocity group contains very many particles." 
 
 Now if we ask the aforesaid two observers what they under- 
 stand by the state of the atomic host or gas under consideration, 
 they will give entirely different answers. The micro-observer 
 will mention those magnitudes which determine the location and 
 the velocity condition of all the individual atoms. This would 
 mean in the simplest case, in which the atoms are regarded as 
 material points, that there would be six times as many magnitudes 
 as atoms present, namely, for each atom there would be three 
 co-ordinates of location and three of velocity components; in 
 the case of composite molecules there would be many more such 
 
AND OF THE SECOND LAW 7 
 
 magnitudes. For the micro-observer, the state and the sequence 
 of the event would not be determined until all these many mag- 
 nitudes had been separately given. The state thus defined we 
 will call the "micro-state." The macroscopic-observer on the 
 other hand gets along with much fewer data; he will say that the 
 state of the contemplated homogeneous gas is already determined 
 by the density, the visible velocity and the temperature at each 
 place of the gas and he will expect, when these magnitudes are 
 given, that the course of the physical events will be completely 
 determined, namely, will occur in obedience to the two laws of 
 thermodynamics and therefore be bound to show an increase in 
 entropy. The state thus denned we will call the "macro-state." 
 The difference in the two observers is that one sees only the atomic 
 events and the other the occurences in the aggregate. The former 
 would have the absolute mechanical idea of state and the latter 
 the statistical idea. Before attempting to reconcile their apparently 
 conflicting conclusions, we will here call attention to some neces- 
 sary relations between the micro-state and the macro-state. 
 In the first place we must remember that all a priori possible 
 micro-states are not realized in nature; they are conceivable 
 but never attain fruition. How shall we select what may be 
 called these natural micro-states? The principles of general 
 dynamics furnish no guide for such selection and so recourse 
 may be had to any dynamic hypothesis whose selection will be 
 fully justified by experience. 
 
 Now PLANCK says: " In order to traverse this path of investi- 
 gation, we must evidently first of all keep in mind all the con- 
 ceivable positions and velocities of the individual atoms, which 
 are compatible with particular values of the density, the velocity 
 and the temperature of the gas, or, in other words, we must con- 
 sider all the micro-states which belong to a particular macro- 
 state and must examine all the different events which follow 
 from the different micro-states according to the fixed laws of 
 dynamics. Now up to this time, the closer calculation and com- 
 
8 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 bination of these minute elements has always given the important 
 result that the vast majority of these micro-states belong to one 
 and the same macro-state or aggregate, and that only compara- 
 tively few of the said micro-states furnish an anomalous result, 
 and these few are characterized by very special and far-reaching 
 conditions existing between the locations and the velocities of 
 adjacent atoms. And, furthermore, it has appeared that the 
 almost invariably resulting macro-event is just the very one 
 perceived by the macroscopic observer, the one in which all 
 the measureable mean values have a unique sequence, and con- 
 sequently and in particular satisfies the second law of thermody- 
 namics." 
 
 " Herewith is revealed the bridge of reconciliation between 
 the two observers. The micro- observer needs only to take up 
 in his theory the physical hypothesis, that all such particular 
 cases (which premise very special, far-reaching conditions between 
 the states of adjacent and interacting atoms) do not occur in 
 Nature; or in other words, the micro-states are in ' elementary 
 disorder ' (elementar ungeordnet). This secures the unique 
 (unambiguous) character of the macroscopic event and makes 
 sure that the Principle of the Growth of Entropy will be satisfied 
 in every direction." 
 
 Before elaborating all that is implied in this hypothesis of 
 " elementary disorder " we will again point out that for each 
 macro-state (even with settled values of density and temperature) 
 there may be many micro-states which satisfy it in the aggregate. 
 According to PLANCK, " it is easy to see that the macro-observer 
 deals with mean values; for what he calls density, visible velocity, 
 temrjerature of the gas, are for the micro-observer certain averages, 
 statistical data, which have been suitably obtained from the 
 spatial arrangement and the velocities of the atoms. But with 
 these averages the micro-observer at first can do nothing even 
 if they are known for a certain time, for thereby the sequence 
 of events is by no means settled; on the contrary, he can easily 
 
AND OF THE SECOND LAW 9 
 
 with said given averages ascertain a whole host of different values 
 for the location and velocities of the individual atoms, all of which 
 correspond to said given averages, and yet some of these lead to 
 wholly different sequences of events even in their mean values," 
 events which do not at all accord with experience. It is evident, 
 if any progress is to be made, that the micro-observer must in 
 some suitable way limit the manifold character of the multi- 
 farious micro-states. This he accomplishes by the hypothesis 
 of " elementary disorder " about to be more fully denned. 
 
 In passing we may here note for future use, that what has 
 just been said concerning macro-states (aggregates) with " settled " 
 mean velocity, density and temperature, applies also to states 
 unsettled in the aggregate, so far as concerns the manifold char- 
 acter of the conceivable constituent micro-states and the dif- 
 ferences in the mean character of their sequences. Even after 
 the above limiting hypothesis removes all illegitimate micro- 
 states, an enormously greater number of legitimate ones will be 
 left to constitute the number of complexions properly belonging 
 to the state contemplated. We may also add that it seems quite 
 evident that the numbers representing these complexions will 
 be different in the settled and unsettled states even if the latter 
 should ultimately possess the mean velocity, density and tem- 
 perature of the former. 
 
 On the other hand, we also point out that for one and the same 
 set of external conditions the macro-state may itself vary very 
 greatly. When it has a settled density and temperature, it is 
 said to be in a stationary state, to be in thermal equilibrium and, 
 anticipating, we may add that it is then has maximum entropy, 
 in short we may say it is in a " normal " condition. But the 
 external conditions remaining the same, before attaining to 
 said " normal " ultimate state, it may pass through a whole 
 series of so-called " abnormal " states after it leaves its initial 
 condition. While it is in any one of these " abnormal " states, 
 it may be said to be in a more or less turbulent condition 5 
 
10 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 it may then possess whirls and eddies; it may have different 
 densities and temperatures in its different parts and then it will 
 be difficult or impossible to measure these external physical 
 features of its state as a whole. All this implies ever-varying 
 atomic locations and velocities, but does not indicate any such 
 special far-reaching regularities between adjacent and inter- 
 acting particles as would vitiate at any stage our hypothesis of 
 " elementary disorder " (elementar ungeordnet) or " molecular 
 chaos." 
 
 Before going into more detail concerning this particular chaotic 
 condition of the particles we will give PLANCK'S somewhat fuller 
 statement of what constitutes the " state " of a physical system 
 at a particular time and under given external conditions. It is, 
 " the conception as a whole of all those mutually independent 
 magnitudes which determine the sequence of events occurring 
 in the system so far as they are accessible to measurement; the 
 knowledge of the state is therefore equivalent to a knowledge 
 of the initial conditions. For example, in a gas composed of 
 invariable molecules the state is determined by the law of their 
 space and velocity distribution, i.e., by the statement of the 
 number of molecules, of their co-ordinates and velocity compo- 
 nents which lie within each single small region. The number 
 of molecules in any one of these different regions is in general 
 entirely independent of the number in any other region, for the 
 state need not be a stationary one nor one of equilibrium; these 
 numbers should therefore all be separately known if the state 
 of the gas is to tie considered as given in the absolute mechanical 
 sense. On the other hand, for the characterization of the state 
 in the statistical sense, it is not necessary to go into closer detail 
 concerning the molecules present in each elementary space; 
 for here the necessary supplement is supplied by the hypothesis 
 of molecular chaos, " which in spite of its mechanically indeter- 
 minate character guarantees the unambiguous sequence of the 
 physical events." 
 
AND OF THE SECOND LAW 11 
 
 (2) Further Elucidation of this Essential Condition of " Elemen- 
 tary Chaos. ' ' Sundry A spects of Haphazard 
 
 To gain as complete an understanding as possible of this funda- 
 mental idea we will now give the views of the several investigators 
 as to the physical features of this chaotic state. We have seen 
 how PLANCK, the chief expositor of BOLTZMANN, boldly excludes 
 from consideration all cases leading to anomalous results, because 
 of the very special conditions existing between the molecular data, 
 by assuming that these cases do not occur in Nature. PLANCK 
 reminds the physicists who object to the hypothesis of elementary 
 disorder because they feel it is unnecessary or even unjustifiable, 
 that the hypothesis is already much used in Physics, that tacitly 
 or otherwise it underlies every computation of the constants 
 attached to friction, diffusion and the conduction of heat. On 
 the other hand he reminds others, those inclined to regard the 
 hypothesis of " elementary disorder " as axiomatic, of the theorem 
 of H. POINCARE, which excludes this hypothesis for all times from 
 a space surrounded with absolutely smooth walls. PLANCK says 
 that the only escape from the portentous sweep of this proposition 
 is that absolutely smooth walls do not exist in Nature. 
 
 The foregoing thought PLANCK has also put in a slightly dif- 
 ferent way. Appreciating that all mechanically possible simul- 
 taneous arrangements and velocities of molecules are not realized 
 in Nature, the concept of " elementary diforder " implies one 
 limitation of the conceivable molecular states, namely that, 
 between the numerous elements of a physical system there exist 
 no other relations than those conditioned by the existing measurable 
 mean values of the physical features of the system in question. 
 
 Another, briefer but equivalent, definition is that: " In Nature 
 all states and processes which contain numerous independent 
 (unkontrollierbar) constituents are in ' elementary disorder ' 
 (elementar ungeordnet) ." The constituents are molecular ele- 
 
12 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 ments in mechanics and in thermodynamics and the energy 
 elements in radiation. 
 
 The German word " unkontr oilier bar ?>1 here used may also 
 with some justice be translated as, unconditioned, undetermined, 
 unmeasurable, unregulated, uncorrelated, ungovernable or hap- 
 hazard. But whichever term is best, PLANCK, mechankally 
 srjeakmg^jneant by it, the confused, unregulated and whirring 
 intermingling of very many atoms. 
 
 Either of these two equivalent definitions implies that such 
 elementary disorder or chaos is a condition of sufficiently com- 
 plete haphazard to warrant the application of the .Theory., of 
 Probabilities to the unique (unambiguous) determination joL the 
 measurable physical features of the process viewed as a whole. 
 
 The foregoing ideas more or less tacitly underlie the whole 
 of B^OLTZM ANN'S great pioneer work in this vast field. He it was 
 who clearly showed that the Second Law could be derived from 
 mechanical principles: that entropy was a property of every 
 state, turbulent or otherwise; that the entropy idea would be 
 emancipated from all thought of human, experimental, skill, 
 and who thereby raised the Second Law to the position of a real 
 principle. He did all this by a general basing of the idea of entropy 
 on the idea of probability. Consequently we find much attention 
 paid in all his work to haphazard molecular conditions. He 
 first used the terms " molekular-geordnet " (molecularly ordered, 
 or arranged), and " molekular ungeordnet " ^ molecular ly dis- 
 ordered or disarranged), which latter phrase we must regard 
 as synonomous with the term " ekmentar ungeordnet " (elemen- 
 tary disorder or chaos) with which we have already become 
 acquainted in PLANCK'S presentation. We will, therefore, con- 
 fine ourselves here to BOLTZMANN'S illustrations of these terms, 
 for his work does not, in these particulars, contain any sharp 
 
 1 On p. 133 of Warmestrahlung PLANCK says, "only measurable mean values 
 are kontrollierbar, " and this may help us to get the meaning here. 
 
AND OF THE SECOND LAW 13 
 
 definitions. Indeed he may have feared over-precision and may 
 have trusted to the use he made of the terms at different tunes 
 to convey their meaning. 
 
 Concerning some of the characteristics of BOLTZM ANN'S hap- 
 hazard motion we take the following from Vol. I of his " Vorle- 
 sungen liber Gas Theorie." 
 
 If in a finite part of. a gas the variables determining the motion 
 of the molecules have different mean values from those in another 
 finite part of the gas (for example if the mean density or mean 
 velocity of a gas in one-half of a vessel is different from those in 
 the other half), or more generally, if any finite part of a gas behaves 
 differently from another finite part of a gas, then such a dis- 
 tribution is said to be " molar-geordnet " (in molar order). 
 But when the total number of molecules in every unit of volume 
 exists under the same conditions and possesses the same number 
 of each kind of molecules throughout the changes contemplated, 
 then the same number of molecules will leave a unit volume and 
 will enter it so that the total number ever present remains the same; 
 under such conditions we call the distribution " molar-ungeordnet " 
 (in molar disorder) and that finite distribution is one of the 
 characteristics of the haphazard state to which the Theory of 
 Probabilities is applicable. [As another illustration of the excluded 
 molar-geordnet states we may instance the case when all motions 
 are parallel to one plane.] 
 
 But although in passing from one finite part to another of a gas 
 no regularities (of average character) can be discerned, yet infin- 
 itesimal parts (say of two or more molecules) may exhibit certain 
 regularities, and then the distribution would be " molekular- 
 geordnet " (molecularly-ordered) although as a whole the gas 
 is " molar-ungeordnet." For example (to take one of the infinite 
 number of possible cases) suppose that the two nearest mole- 
 cules always approached each other along their line of centers, 
 or if a molecule moving with a particularly slow speed always 
 had ten (10) slow neighbors, then the distribution would be 
 
14 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 " molekular-geordnet." But then the locality of one molecule 
 would have some influence on the locality of another molecule 
 and then in the Theory of Probabilities the presence of one mole- 
 cule in one place would not be independent of the presence of 
 some other molecule in some other place. Such dependence 
 is not permissible by the Theory of Probabilities. Before, how- 
 ever, we can further describe what is here perhaps the most impor- 
 tant term (molekular-ungeordnet), we must point out that BOLTZ- 
 MANN considers the number of molecules m of one kind whose 
 component velocities along the co-ordinate axes are confined 
 between the limits, 
 
 and +d, t) and y+dr), and d^, . . (i) 
 
 and also the number of molecules mi of another kind whose 
 component velocities similarly lie between the limit 
 
 i*i + i, gi*fli+<fyi, Si *-!, ... (2) 
 
 then, considering the chances that a molecule m shall have 
 velocities between the limits specified in (i) and molecule mi 
 have velocities between limits (2), BOLTZMANN intimates that these 
 chances are independent of the relative position of the molecules. 
 Where there is such complete independence, or absence of all 
 minute regularities, the distribution, according to BOLTZMANN, 
 is " molekular-ungeordnet " (molecular ly-disordered). 
 
 BOLTZMANN furthermore informs us that, as soon as in a gas, 
 the mean length of path is great in comparison with the mean dis- 
 tance between two adjacent molecules, the neighboring molecules 
 will quickly become different from what they formerly were. 
 Therefore it is exceedingly probable that a " molekular-geord- 
 nete " (but molar-ungeordnete) distribution would shortly pass 
 into a " molekular-ungeordnete " distribution. 
 
 Furthermore, from the constitution of a gas results that the 
 place where a molecule collided is entirely independent of the 
 spot where its preceding collision took place. Of course, this 
 
AND OF THE SECOND LAW 15 
 
 independence could be maintained for an indefinite time only 
 by an infinite number of molecules. 
 
 The place of collision of a pair of molecules must in our 
 Theory of Probabilities be independent of the locality from 
 which either molecule started. 
 
 From all the preceding we must infer what measure of hap- 
 hazard BOLTZMANN considers necessary for the legitimate use of 
 the Theory of Probabilities. 
 
 BOLTZMANN in proving his H-Theorem, 1 which establishes the 
 one-sidedness of all natural events, makes the explicit assumption 
 that the motion at the start is both " molar- und molekular- 
 ungeordnet " and remains so. Later on, he assumes the same 
 things but adds that if they are not so at the start they will soon 
 become so; therefore said assumption does not preclude the con- 
 sideration by Probability methods of the general case or the 
 passage from " ordnete " to " ungeordnete " conditions which 
 characterizes all natural events. 
 
 In fact these very definitions show solicitude for securing the 
 uninterrupted operation of the laws of probability. BOLTZMANN 
 intimates his approval of S. H. BURBURY'S statement of the con- 
 dition of independence underlying his work. 
 
 Here S. H. BURBURY 2 simplifies the matter by assuming that 
 any unit of volume of space contains a uniform mixture of 
 differently speeded molecules and then says: 
 
 " Let V be the velocity of the center of gravity of any pair of 
 molecules and R their relative velocity. Then the following 
 condition (here called A) holds: For any given direction of R 
 before collision, all directions of R after collision are equally 
 probable. Then BOLTZMANN'S H-theorem proves that if con- 
 dition A be satisfied, then if all directions of the relative velocity 
 R for given V are not equally likely, the effect of collisions 
 
 1 In BOLTZMANN'S H-Theorem we have a process (consisting of a number of 
 separately reversible processes) which is irreversible in the aggregate. 
 
 2 Nature, Vol. LI, p. 78, Nov. 22, 1894. 
 
16 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 is to make H diminish." [In essence BURBURY'S condition 
 A says no more than that Theory of Probabilities is applicable 
 for finding number of collisions.] Furthermore, " any actual 
 material system receives disturbances from without, the effect 
 of which coming at haphazard without regard to state of 
 system for the time being is, pro tanto, to renew or maintain 
 the independence of the molecular motions, that very distribu- 
 tion of co-ordinates (of collision) which is required to make 
 H diminish. So there is a general tendency for H to diminish, 
 though it may conceivably increase in particular cases. Just 
 as in matters political, change for the better is possible, but the 
 tendency is for all change to be from bad to worse." Here 
 BURBURY states what is practically true in all actual cases and 
 thus furnishes an additional reason, if that were needed, for the 
 legitimacy of the Probability method pursued by BOLTZMANN, and, 
 another explanation of why the results obtained are in such per- 
 fect accord with experience. 
 
 AsBuRBURY'sremarkswith respect to the nature of "elementary 
 chaos " under consideration are always illuminating, we will, 
 at the risk of repeating something already said, quote the following: 
 
 " The chance that the spheres approaching collision shall 
 have velocities within assigned limits is independent of their 
 relative position, and of the positions and velocities of all other 
 spheres, and also independent of the past history of the system 
 except so far as this has altered the distribution of the velocities 
 inter se. In the following example this independence is satisfied 
 for the initial state and, for the assumed method of distribution, 
 has no past history. 
 
 " Example. A great number of equal elastic spheres, each of 
 unit mass and diameter a, are at an initial instant set in motion 
 within a field S of no force and bounded by elastic walls. The 
 initial motion is formed as follows: (i) One person assigns com- 
 ponent velocities , v, w to each sphere according to any law 
 subject to the conditions that 2u=I>v=I,w=Q and that 
 
AND OF THE SECOND LAW 17 
 
 a given constant. (2) Another person, in com- 
 plete ignorance of the velocities so assigned, scatters the spheres 
 at haphazard throughout S. And they start from the initial 
 positions so assigned by (2) with the velocities assigned to them 
 respectively by (i)." 
 
 The system thus synthetically constructed would without 
 doubt, at the start be " molekular-ungeordnet " in fact, it is as 
 near an approach to chaos as is possible in an imperfect world. 
 But there is reason to doubt if it would continue to be thus " molek- 
 ular-ungeordnet." For the distribution of velocities is according 
 to any law consistent with the above-mentioned conditions and 
 some such laws would lead to results hostile to the Second Law, 
 and then we may safely say such laws of velocity distribution 
 would never occur in Nature and would therefore belong to the 
 cases which have been specially excepted. 
 
 Now there are mechanical systems which possess the entropy 
 property and it has been truly said that the Second Law and irre- 
 versibility do not depend on any special peculiarity of heat motion, 
 but only on the statistical property of a system possessing an 
 extraordinary number of degrees of freedom. In this sense 
 Professor J. W. GIBBS treated Mechanics statistically and showed 
 that then the properties of temperature and entropy resulted. 
 This matter has already been touched upon, but as numerous 
 degrees of freedom is a feature of the " elementary chaos " under 
 consideration it deserves repetition here and more than a passing 
 mention. 
 
 Illustration of Degrees of Freedom. Refer a body's motion to 
 three axes, X, Y, Z. If a body has as general a motion as possible, 
 it may be resolved into translations parallel to the X, F, Z axes 
 and to rotations about these axes. Each of these two sets furnishes 
 three components of motion or a total of six components; then 
 we say that the perfectly unconstrained motion of the body has 
 six degrees of freedom. If a body moves parallel to one of the 
 co-ordinate planes, we say it has two degrees of freedom. When 
 
18 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 we come to consider molecular motion in general and the inde- 
 pendence which characterizes the motion of each of the many 
 molecules we see that altogether we have here an extraordinary 
 number of degrees of freedom, and composed of such is the realm 
 of our " elementary chaos." 
 
 If we go to the other extreme and think of only one atom, 
 we see at once that we cannot properly speak of its disorder. 
 But the case is different with a moderate number of atoms, say, 
 a hundred or a thousand. Here we surely can speak of disorder 
 if the co-ordinates of location and the velocity components are 
 distributed by haphazard among the atoms. But as the process 
 as a whole, the sequence of events in the aggregate, may not 
 with this comparatively small number of atoms take place before 
 a macroscopic observer in a unique (unambiguous) manner, 
 we cannot say that we have here reached a true state of " elemen- 
 tary chaos." If we now ask as to the minimum number of atoms 
 necessary to make the process an irreversible one, the answer is, 
 as many as are necessary to form determinate mean values which 
 will define the progress of the state in the macroscopic sense. 
 Only for these mean values does the Second Law possess signifi- 
 cance; for these, however, it is perfectly exact, just as exact as 
 the theorem of probability, which says that the mean value of 
 numerous throws with one cubical die is equal to 3^. 
 
 We may now properly infer from all these views that the 
 state of " elementary chaos " (or " molekular ungeordnete " 
 motion) is the necessary condition for adequate haphazard and 
 makes the application of the Theory of Probabilities possible. 
 
 (3) Settled and Unsettled States; Distinction between Final Stage 
 of Elementary Chaos and its Preceding Stages 
 
 The immediate purpose in the next few pages is to establish 
 the (a) distinction between the successive stages of " elementary 
 disorder " (chaos) as they develop in their inevitable passage 
 
AND OF THE SECOND LAW 19 
 
 from " abnormal " conditions to the final and so-called " normal " 
 condition of thermal equilibrium and, furthermore, (b) to show that 
 each of these stages is " elementar-ungeordnet " and (c) that in 
 each one sufficient haphazard prevails to permit the legitimate 
 application of the Theory of Probabilities. 
 
 We will first describe the unsettled (abnormal) and settled 
 (normal) states, respectively. When we consider the general 
 state of a gas " we need not think of the state of equilibrium, 
 for this is still further characterized by the condition that its 
 entropy is a maximum. Hence in the general or unsettled state 
 of the gas an unequal distribution of density may prevail, any 
 number of arbitrarily different streams (whirls and eddies) may 
 be present, and we may in particular assume that there has taken 
 place no sort of equalization between the different velocities of the 
 molecules. We may assume beforehand, in perfectly arbitrary 
 fashion, the velocities of the molecules as well as their co-ordinates 
 of location. But there must exist (in order that we may know 
 the state in the macroscopic sense) , certain mean values of density 
 and velocity, for it is through these very mean values that the 
 state is characterized from the macroscopic standpoint." The 
 differences that do exist in the successive stages of disorder of the 
 the unsettled state are mainly due to the molecular collisions 
 that are constantly taking place and which thus change the 
 locus and velocity of each molecule. 
 
 We may now easily describe the settled state as a special case 
 of the unsettled one. In the settled state there is an equal dis- 
 tribution of density throughout all the elementary spaces, there 
 are no different streams (whirls or eddies) present, and an equal 
 partition of energy exists for all the elementary spaces. For it 
 tKermal equilibrium exists, the entropy is a maximum, and tem- 
 perature of the state has now a definite meaning, because tem- 
 perature is the mean energy of the molecules for this state of 
 equilibrium. The condition is said to be a " stationary " or 
 permanent one, for the mean values of the density, velocity, and 
 
20 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 temperature of this particular aggregate no longer change, 
 although molecular collisions are still constantly occurring. 
 
 Well-known examples of the unsettled state of a system are: 
 The turbulent state with its different streams, whirls, and eddies, 
 the state in which the potential and kinetic energy is unequally 
 distributed; for instance, when one part is at a high pressure 
 and another part at a lower pressure, when one part is hotter 
 than another part, and when unmixed gases are present in a 
 communicating system. 
 
 A more specific feature of the unsettled state may be found 
 in the accompaniment to BURBURY'S condition A (already men- 
 tioned at bottom of p. 15) where it is intimated that (at the start 
 and after collision) all directions of the relative velocity R may 
 not be equally likely. 
 
 When such differences have all disappeared to the extent that 
 equal elementary spaces possess their equal shares of the different 
 particles, velocities, and energies, the system will be a settled 
 one, be in thermal equilibrium, and will possess a maximum 
 entropy and a definite temperature. Moreover, BURBURY'S con- 
 dition A is here fully satisfied. 
 
 At this point we again call attention to the fact, that in both 
 the unsettled and settled states of a system all conceivable micro- 
 states are not equally likely to obtain. On p. 9 mention 
 was made that the unsettled and the settled state each pos- 
 sessed a host of conceivable micro-states which agreed with the 
 characteristic averages of their respective macro-states (the 
 unsettled and the settled ones), and yet in each set some of these 
 led subsequently to events which did not accord with experience. 
 Therefore for both the unsettled and the settled state we must 
 limit the manifold character of their micro-states by eliminating 
 all those micro-states which lead to results contrary to experience. 
 This is accomplished by assuming the hypothesis of " elementary- 
 disorder " (elementar-ungeordnet) to obtain for the unsettled as 
 well as the settled state. Now so far as the haphazard character 
 
AND OF THE SECOND LAW 21 
 
 of the remaining motions are concerned, we might stop right here, 
 for the very nature of this hypothesis insures results in harmony 
 with experience, i.e., with the undisturbed operation of the laws 
 of probability. 
 
 But if we do not stop here, preferring to examine some of the 
 special features of fortuitous motion, as detailed on pp. 10, 13, 14 
 and 17, we still see that by this hypothesis we have not removed 
 the haphazard character of the remaining motions in either the 
 unsettled or the settled state. For instance, we have not 
 removed BURBURY'S condition A. We must remember, too, that 
 in PLANCK'S briefest statement of "elementary disorder" (bot. of 
 p. n), two important features of haphazard are emphasized, viz.: 
 the independence and great number of the constituents. BOLTZ- 
 MANN in his Gas Theorie of course considers the special features 
 which underlie the application of the Calculus of Probabilities; 
 thus he says they are, the great number of molecules and the 
 length of their paths, which together make the laws of the colli- 
 sion of a molecule in a gas independent of the place where it 
 collided before. Neither has the introduction of the hypothesis 
 of "elementary disorder" done away with these special features. 
 There have simply been excluded trom consideration such pre- 
 computed and prearranged regularities in the paths and direc- 
 tions of molecules as purposely interfere with the operation of 
 the laws of probability. We are still free to consider all the imagin- 
 able positions and velocities of the individual molecules which are 
 compatible with the mean velocity, density, and temperature 
 properly characteristic of each stage of the passage from the 
 unsettled to the settled state. For adequate haphazard we only 
 need the assumption that the molecules fly so irregularly as to 
 permit the operation of the laws of probabilities. Such a presen- 
 tation as this of course calls for complete trust that all the specified 
 requirements have been adequately met and BOLTZMANN'S emi- 
 nence as a mathematical physicist and the endorsement of his peers 
 must be our guarantee for such confidence and trust. 
 
22 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 Before closing this discussion of unsettled and settled states 
 we will insert here two remarks, really at this stage, anticipatory in 
 their nature. The first is, that under the limitation imposed by our 
 supplementary hypothesis of " elementary chaos," the very sharpest 
 definition of any macro-state is the number of its possible micro- 
 states. This is evidently the number of permutations, possible with 
 the given locus and velocity elements under the restriction imposed 
 above. Later on we will find that this number of possible micro- 
 states is smaller for the unsettled state than for the settled one. 
 This gives us a clean-cut distinction between the two states con- 
 templated. The second remark is that the inevitable change in 
 the system as a whole is always from the less probable to the more 
 probable, is a passage from an unsettled state of the system to 
 its settled state and this is here synonymous with the growth of the 
 number of possible micro-states. It is this difference between the 
 initial and final states which constitutes the universal driving 
 motive in all natural events. 
 
 SECTION B 
 
 THE APPLICATION OF CALCULUS OF PROBABILITIES 
 IN MOLECULAR PHYSICS. 
 
 (i) The Probability Concept, its Usefulness in the Past, its Present 
 Necessity, and its Universality. 
 
 An indication of its essential value in this physical discussion 
 is evidenced by the fact that we have almost unwittingly been forced 
 to constantly refer to it in all of our preliminaries. But when 
 this concept is first broached to a student, he feels about it like 
 the "man in the street"; it is by the latter regarded as a matter 
 of chance and hence of uncertainty and unreliability; moreover, 
 the latter knows in a vague way that the subject has to do with 
 averages, that it is often of a statistical nature, and knows that 
 statistics in general are widely distrusted. The student is at 
 
AND OF THE SECOND LAW 23 
 
 first likely to share these views with said man in the street, and 
 at best feels that its introduction is of remote interest, far fetched, 
 and tends to hide and dissipate the kernel of the matter. The 
 student must disabuse himself of these false notions by reflecting 
 how much there is in Nature that is spontaneous, in other words, 
 how many events there are in which there is a passage from a 
 less probable to a more probable condition and that he cannot 
 afford to despise or ignore a Calculus which measures these 
 changes as exactly as possible. 
 
 In this connection BOLTZMANN says: (W. S. B. d. Akad. d. 
 Wiss., Vol. LXVI, B 1872, p. 275). 
 
 "The mechanical theory of heat assumes that the molecules 
 of gases are in no way at rest but possess the liveliest sort of motion, 
 therefore, even when a body does not change its state, every one 
 of its molecules is constantly altering its condition of motion and 
 the different molecules likewise simultaneously exist side by side 
 in most different conditions. It is solely due to the fact that we 
 always get the same average values, even when the most irregular 
 occurences take place under the same circumstances, that we can 
 explain why we recognize perfectly definite laws in warm bodies. 
 For the molecules of the body are so numerous and their motions 
 so swift that indeed we do not perceive aught but these average 
 values. We might compare the regularity of these average values 
 with those furnished by general statistics which, to be sure, are 
 likewise derived from occurrences which are also conditioned by 
 the wholly incalculable co-operation of the most manifold external 
 circumstances. The molecules are as it were like so many indi- 
 viduals having the most different kinds of motion, and it is only 
 because the number of those which on the average possess the 
 same sort of motion is a constant one that the properties of the 
 gas remain unchanged. The determination of the average values 
 is the task of the Calculus of Probabilities. The problems of 
 the mechanical theory of heat are therefore problems in this 
 calculus. It would, however, be a mistake to think any uncertainty 
 
24 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 is attached to the theory of heat because the theorems of probability 
 are applied. One must not confuse an imperfectly proved proposi- 
 tion (whose truth is consequently doubtful) with a completely estab- 
 lished theorem of the Calculus of Probabilities; the latter represents, 
 like the result of every other calculus, a necessary consequence 
 of certain premises, and if these are correct the result is confirmed 
 by experience, provided a sufficient number of cases has been 
 observed, which will always be the case with Heat because of the 
 enormous number of molecules in a body." 
 
 To become more specific we will mention some of the problems 
 to which the Theory of Probabilities has been profitably applied. 
 In business to life and fire insurance; in engineering to reducing 
 the inevitable errors of observations by the Method of Least 
 Squares; and in physics to the determination of Maxwell's Law 
 of the distribution of velocities. The results thus obtained are 
 universally trusted and accepted by experts. Why then should 
 this Calculus not be applicable to the more general natural events ? 
 
 In this connection consider some of its good points: (a) It 
 eliminates from a problem the accidental elements if the latter 
 are sufficiently numerous; (b) it deals legitimately with averages; 
 
 (c) it involves combination considerations other than averages; 
 
 (d) it is available for non-mechanical as well as mechanical occur- 
 rences and thus (e) has a capacity for covering the whole range 
 of natural events^ giving it a character of universality which is 
 now its most valuable asset. 
 
 As an example of this we may instance BOLTZMANN'S deservedly 
 famous H-theorem, which establishes the one-sidedness of all 
 natural events. 1 Concerning it, this master in mathematical 
 physics says: 
 
 " It can only be deduced from the laws of probability that, if the 
 initial state is not especially arranged ior a certain purpose, the 
 
 1 The H-theorem considers a process (consisting of a number of separate, 
 reversible processes) which is irreversible in the aggregate. 
 
AND OF THE SECOND LAW 25 
 
 probability that H decreases is always greater than that it increases. 
 In this connection we may add that BOLTZMANN looked forward 
 to a time," when the fundamental equations for the motion of 
 individual molecules will prove to be merely approximate formulas, 
 which give average values which, according to the Theory of 
 Probabilities, result from the co-operation of very many inde- 
 pendently moving individuals constituting the surrounding 
 medium, for example, in meteorology the laws will refer only to 
 average values deduced by the Theory of Probabilities from a 
 long series of observations. These individuals must of course be 
 so numerous and act so promptly that the correct average values 
 will obtain in millionths of a second." 
 
 To further strengthen our faith we may point out that the 
 probability method has been successfully used to determine 
 unique results from complicated conditions and has been employed 
 for the general treatment of problems. In the case before us 
 it has solved the entropy puzzle which has exercised physicists, 
 as well as engineers, for decades, and it has thereby emancipated 
 the Second Law from all anthropomorphism, from all dependence 
 on human experimental skill. When we take the broadest 
 possible view of its character, this Calculus enables us to read 
 the present riddle of our universe, namely, why it is in its present 
 improbable state. We have therefore in this Calculus an engine 
 for investigation which is of great power and is likely to play a 
 large part in the future in the ascertainment -of physical truth. 
 Of course it must then be in the hands of masters. It is they 
 and they alone who can properly and adequately interpret such 
 a physical problem as the one before us. In scientific work our 
 last court of appeal must be Nature, and we therefore say: The 
 best justification for the use of the Theory of Probabilities in our 
 problem is that its results are in such complete accord with the 
 facts. 
 
 In dealing with this physical engine of investigation, we must 
 again call attention to some of the features of haphazard necessary 
 
26 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 for its legitimate application. Of course the statement of these 
 features will vary with the mechanical or non-mechanical character 
 of the problem to which it is applied. As we are here dealing 
 mainly with the former, we will limit ourselves to its features : (a) 
 The elements dealt with must be very numerous, strictly speaking, 
 infinite; (b) as a phase of (a) we may say also that when we 
 speak of the probability of a state we express the thought that 
 it can be realized in many different ways; (c) when we speak 
 of the relative directions of a pair of molecules all possible direc- 
 tions must be considered; (d) we must so weight the elements 
 say, in (a), (&), and (c) that they are equally likely; (e) every one 
 of the entering elements must possess constituents of which each 
 individual is independent of every other; for instance, (/) in a gas 
 the place where a molecule collided must be independent of the 
 place where it collided before. In our physical problem all of 
 these features are not always realized; for instance, the number 
 of particles of gas are only finite instead of being infinite; 
 again, all relative velocities after collision of a pair of molecules 
 are not equally likely; BOLTZMANN and BURBURY provide for these 
 shortcomings by very truly asserting that in actual cases we are 
 not dealing with isolated systems, that the surrounding walls 
 are not impervious to external influences, and that the latter 
 come at haphazard without regard to internal state of the system 
 at the time, thus renewing and maintaining the desired state of 
 haphazard. 
 
 Methods. This Calculus works largely by the determination 
 of averages and its results must be interpreted accordingly. 
 Moreover, for the present we will take a popular, practical view 
 of these results and consider a very great improbability as equiva- 
 lent to an impossibility. Numerical computations are essential 
 in most uses of this Calculus, but here they will be entirely omitted. 
 
AND OF THE SECOND LAW 27 
 
 (2) What is Meant by the Probability of a State ? Example 
 
 To come back to the matter in hand we will now show what 
 is here meant by the probability of any state. 
 
 When we speak of the probability W of a particular " elementar- 
 ungeordnete " state, we thereby imply that this state may be 
 variously realized. For every state (which contains many like 
 independent constituents) corresponds to a certain " distribu- 
 tion," namely, a distribution among the gas molecules of the 
 location co-ordinates and of the velocity components. But such 
 a distribution is a permutation problem, is always an assignment 
 of one set of like elements (co-ordinates, velocity components) 
 to a different set of like elements (molecules). So long as only a 
 particular state is kept in view, it is of consequence as to how 
 many elements of the two sets are thus interchangeably assigned 
 to each other and not at all as to which individual elements of 
 the one set are assigned to particular individual elements of the 
 other set. 1 Then a particular state may be realized by a great 
 number of assignments individually differing from one another, 
 but all equally likely to occur. 2 If with PLANCK we call such an 
 assignment a " complexion," 3 we may now say that in general a 
 particular state contains a large number of different, but equally 
 likely, complexions. This number, i.e., the number of the com- 
 plexions included in a given state can now be defined as the proba- 
 bility W of the state* 
 
 Let us present the matter in still another form. BOLTZMANN 
 derives the expression for magnitude of the probability by at 
 
 1 For an example of such permutations see pp. 28 and 61, 62. 
 
 2 LIOUVILLE'S theorem is the criterion for the equal possibility or equal proba- 
 bility of different state distributions. 
 
 3 A happy term, but one not in vogue among English-speaking physicists. 
 
 4 The identity of entropy with the logarithm of this state of probability W 
 is established by showing that both are equal to the same expression. It seems 
 an easy step from this derivation to BOLTZMANN'S definition of entropy as the 
 "measure of the disorder of the motions in a system of mass points." 
 
28 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 once distinguishing between a state of a considered system and 
 the complexion of the considered system. A state of the system is 
 determined by the law of locus and velocity distribution, i.e., by 
 a statement of the number of particles which lie in each ele- 
 mentary district of space and the number of particles which lie in 
 each elementary velocity realm, assuming that among themselves 
 these districts and realms are alike and each such infinitesimal 
 element still harbors very many particles. Accordingly a particu- 
 lar state of the system embraces a very large number of com- 
 plexions. For if any two particles belonging to different regions 
 swap their co-ordinates and velocities, we get thereby a new 
 complexion, but still the same state. Now BOLTZMANN assumes all 
 complexions to be equally probable and therefore the number of 
 complexions included hi a particular state furnishes at the same 
 time the numerical value for the Probability of the state in 
 question. Illustration taken from the simultaneous throwing of 
 two, ordinary, cubical dice. Suppose that the sum is to be 4 for 
 each throw, then this can be realized by the following three com- 
 plexions: 
 
 First cube shows i, the second cube shows 3; 
 First cube shows 2, the second cube shows 2; 
 First cube shows 3, the second cube shows i. 
 
 The requirement that the sum on the two cubes shall be 2, how- 
 ever, involves but one complexion. Under the circumstances 
 therefore the probability of throwing the sum 4 is three times 
 as great as throwing the sum 2. 
 
 In closing this part of our presentation, we may make what is 
 now an almost obvious remark. The long-lasting difficulty in 
 giving a physical meaning to entropy and the Second Law is due 
 to the fact of its intimate dependence on considerations of prob- 
 ability. It is only quite recently that such considerations have 
 attained the dignity of a great working principle in the domain of 
 Physics. 
 
AND OF THE SECOND LAW 29 
 
 SECTION C 
 
 (i) Existence, Definition, Measure, Relations, Properties, and 
 Scope of Irreversibitity and Reversibility. 
 
 In establishing the existence of irreversibility, we can use 
 one or both of the two general methods of approaching any physical 
 problems (see Introduction, pp. 2, 3) we can approach by way 
 of the atomic theory or by considering the behavior of aggregates 
 in Nature. Enough has already been said in this presentation 
 of atomic behavior and arrangements to justify the statement 
 that irreversibility is not inherent in the elementary procedures 
 themselves but in their irregular arrangement. The motion 
 of each atom is by itself reversible, but their combined mean 
 effect is to produce something irreversible. 1 
 
 This has been rigorously demonstrated by BOLTZMANN'S H- 
 theorem for molecular physics, and when sufficiently general 
 co-ordinates are substituted it is also available for the other domains 
 of natural events. When we consider the behavior of aggregates 
 we recognize at once a general, empirical law, which has also 
 been called the one physical axiom, namely, that all natural 
 processes are essentially irreversible. When we use this method 
 of approach we confessedly rest entirely on experience, and then 
 it does not make any logical difference whether we start with 
 one particular fact or another, whether we start with a fact itself 
 or its necessary consequence: For instance we may recognize 
 that the universe is permanently different after a frictional event 
 from what it was before, or we may start, as PLANCK does, by 
 putting forward the following proposition: 
 
 " // is impossible to construct an engine which will work in 
 
 1 This would seem to imply the existence of a broader principle, the properties 
 of systems as a whole are not necessarily found in their parts. 
 
30 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 a complete cycle, 1 and produce no effect except the raising of a 
 and the cooling of a heat reservoir" 2 
 
 Now up to this time no natural event has contradicted this 
 theorem or its corollaries. The proof for it is cumulative, wholly 
 experiential and therefore exactly like that for the law of con- 
 servation of energy. 
 
 Returning to irreversibility, the matter for immediate dis- 
 cussion, we premise that it will here clarify and simplify our 
 ideas if we consider all the participating bodies as parts of the 
 system experiencing the contemplated process. It is in this 
 v sense that we must understand the statement : Every natural 
 event leaves the universe different from what it was before. 
 Speaking very generally, we may say that in this difference lies 
 what we call irreversibility. 
 
 Now irreversibility is what really does exist, everywhere in 
 Nature, and our idea of reversibility is only a very convenient 
 and fruitful fiction; our conception of reversibility must, there- 
 fore, ultimately be derived from that of irreversibility. 
 
 " A process which can in no way be completely reversed 
 is termed irreversible, all other processes reversible. That a 
 process may be irreversible, it is not sufficient that it cannot be 
 directly reversed. This is the case with many mechanical processes 
 which are not irreversible (See p. 32). The full requirement 
 is, that it be impossible, even with the assistance of all agents 
 in Nature, to restore everywhere the exact initial state when the 
 
 H process has once taken place."/ 
 , Examples of irreversible processes, which involve only heat 
 and mechanical phenomena, may be grouped in four classes: 
 
 (a) The body whose changes of state are considered is in 
 contact with bodies whose temperature differs by a finite amount 
 
 1 Such an engine if it would work might be called " perpetual motion of the 
 second kind." 
 
 2 The term perpetual is justified because such an engine would possess the most 
 esteemed feature of perpetual motion power production free of cost. 
 
 
AND OF THE SECOND LAW 31 
 
 from its own. There is here flow of heat from the hotter to the 
 colder body and the process is an irreversible one. 
 
 (b) The body experiences resistance from friction which 
 develops heat; it is not possible to effect completely the opposite 
 operation of restoring the whole system to its initial state. 
 
 (c) The body expands without at the same time developing 
 an amount of external energy which is exactly equal to the work 
 of its own elastic forces. For example, this occurs when the 
 pressure which a body has to overcome is essentially (i.e., finitely) 
 less than the body's own internal tension. In such a case it is 
 not possible to bring the whole system (of which the body is a 
 part) completely back into its initial state. Illustrations are: 
 steam escaping from a high-pressure boiler, compressed air flowing 
 into a vacuum tank, and a spring suddenly released from its 
 state of high tension. 
 
 (d) Two gases at the same pressure and temperature are 
 separated by a partition. When this is suddenly removed, the 
 two gases mix or diffuse. This too is an essentially irreversible 
 process. 
 
 Outside of chemical phenomena, we may instance still other 
 examples of irreversible processes: flow of electricity in conductors 
 of finite resistance, emission of heat and light radiation, and 
 decomposition of the atoms of radio-active substances. 
 
 " Numerous reversible processes can at least be imagined y 
 as, for instance, those consisting throughout of a succession of 
 states of equilibrium, and therefore directly reversible in all their 
 parts. Further, all perfectly periodic processes, e.g., an ideal 
 pendulum or planetary motion, are reversible, for, at the end of 
 every period the initial state is completely restored. Also, all 
 mechanical processes with absolutely rigid bodies and incom- 
 pressible liquids, as far as friction can be avoided, are reversible. 
 By the introduction of suitable machines with absolutely unyield- 
 ing connecting-rods, frictionless joints, and bearings, inextensible 
 belts, etc., it is always possible to work the machine in such a 
 
32 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 way as to bring the system completely into its initial state without 
 leaving any change in or out of the machines, for the machines 
 of themselves do not perform any work." 
 
 Other examples of such reversible processes are: Free fall in 
 a vacuum, propagation of light and sound waves without absorp- 
 tion and reflection and unchecked electrical oscillations. All the 
 latter processes are either naturally periodic, or they can be made 
 completely reversible by suitable devices so that no sort of change 
 in Nature remains behind; for example, the free fall of a body 
 by utilizing the velocity acquired to bring the body back to its 
 original height, light and sound waves by suitably reflecting them 
 from perfect mirrors. 
 
 (2) Character of Process Decided by the Limiting States 
 
 " Since the decision as to whether a particular process is irre- 
 versible or reversible depends only on whether the process can 
 in any manner whatsoever be completely reversed or not, the 
 nature of the initial and final states, and not the intermediate 
 steps of the process, entirely settle it. The question is, whether 
 or not it is possible, starting from the final state, to reach the 
 initial one in any way without any other change. . . . The final 
 state of an irreversible process is evidently in some way discrimi- 
 nate from the initial state, while in reversible processes the two 
 states are in certain respects equivalent. . . . To discriminate 
 between the two states they must be fully characterized. Besides 
 the chemical constitution of the systems in question, the physical 
 conditions, viz., the state of aggregation, temperature, and pressure 
 in both states, must be known, as is necessary for the application 
 of the First Law." 
 
 11 Let us consider any process whatsoever occurring in Nature. 
 This conducts all participating bodies from a particular initial 
 condition A to a certain final condition B. The process is 
 either reversible or irreversible, any third possibility being 
 
AND OF THE SECOND LAV/ 33 
 
 excluded. But whether it is reversible or irreversible depends 
 solely and only on the constitution of the two states A and B, 
 not upon the other features of the course; after state B has been 
 attained, we must here simply answer the question whether the 
 complete return to A can or cannot be effected in any manner 
 whatsoever. Now if such complete return from B to A is not 
 possible then evidently state B in Nature is somehow distin- 
 guished from state A. Nature may be said to prefer state B to 
 state A. Reversible processes are a limiting case; here Nature 
 manifests no preference and the passage from the one to other 
 can take place at pleasure, in either direction. [In the common 
 case of isentropic expansion from A to J5, there is no exchange 
 of heat with the outside; external work is performed at the 
 expense of the inner energy of the expanding body. When 
 state B is attained we can effect a complete return to A by com- 
 pressing isentropically, thus consuming the external work per- 
 formed on the trip from A to B and restoring the internal energy 
 of the body.] 
 
 "Now it becomes a question of finding a physical magnitude 
 whose amount will serve as a general measure of Nature's preference 
 for a state. This must be a magnitude which is directly determined 
 by the state of the contemplated system, without knowing any- 
 thing of the past history of the system, just as is the case when 
 we deal with the state's energy, volume, etc. This magnitude 
 would possess the property of growing in all irreversible processes, 
 while in all reversible processes it would remain unchanged. 
 The amount of its change in a process would furnish a general 
 measure for the irreversibility of the process." 
 
 " Now R. CLAUSIUS really found such a magnitude and called 
 it entropy. Every bodily system possesses in every state a 
 particular entropy, and this entropy designates the preference 
 of nature for the state in question; in all the processes which 
 occur in the system, entropy can only grow, never dimmish. 
 If we wish to consider a process in which said system is subject to 
 
34 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 influences from without, we must regard the bodies exerting 
 such influences as incorporated with the original system and 
 then the statement will hold in the above given form." 
 
 From what has gone before it is evident that the following 
 commonly drawn conclusions are correct: 
 
 An irreversible process is a passage from a less probable to 
 a more probable state of the system. 
 
 An irreversible process is a passage from a less stable to a 
 more stable state of the system. 
 
 An irreversible process is essentially a spontaneous one, inas- 
 much as once started it will proceed without the help of any external 
 agency. 
 
 We have in a general way reached the conclusion that entropy 
 is both the criterion and the measure of irreversibility. But now 
 let us become more specific and go more into certain details, 
 namely, the common features in all irreversibility. The property 
 of irreversibility is not inherent in the elementary occurrences 
 themselves, but only in their irregular arrangement. Irreversi- 
 bility depends only on the statistical property of a system possess- 
 ing many degrees of freedom, and is therefore essentially based 
 on mean values; in this connection we may repeat an earlier 
 statement, the individual motions of atoms are in themselves 
 reversible, but their result in the aggregate is not. 
 
 (3) All the Irreversible Processes Stand or Fall Together 
 
 This is proved with the help of the theorem (p. 30) which denies 
 the possibility of perpetual motion of the second kind. 1 The 
 argument is this: take any case in any one of the four classes of 
 irreversible processes given on p. 31. Now if this selected case 
 
 1 At this stage we appreciate that any irreversible process is a passage from a 
 state A of low entropy to a state B of high entropy. We may simplify our proof 
 by considering the return passage from B to A to in part occur isothermal ly 
 and in part isentropically; then external agencies must produce work and absorb 
 an equivalent amount of heat. 
 
AND OF THE SECOND LAW 35 
 
 is in reality reversible, i.e., suppose a method were discovered 
 of completely reversing this process and thus leave no other change 
 whatsoever, then combining the direct course of the process with 
 this latter reversed process, they would together constitute a 
 cyclical process, which would effect nothing but the production 
 of work and the absorption of an equivalent amount of heat. 
 But this would be perpetual motion of the second kind, which 
 to be sure is denied by the empirical theorem on p. 30. But for 
 the sake of the argument we may just now waive said impossibility; 
 then we would have an engine which, co-operating with any 
 second (so-called), irreversible process, would completely restore 
 the initial state of the whole system without leaving any other 
 change whatsoever. Then under our definition on p. 30 this 
 second process ceases to be irreversible. The same result will 
 obtain for any third, fourth, etc. So that the above proposition 
 is established. " All the irreversible processes stand or fall together." 
 If any one of them is reversible all are reversible. 1 
 
 (4) Convenience of the Fiction, the Reversible Processes 
 
 A reversible process we have declared to be only an ideal case, 
 a convenient and fruitful fiction which we can imagine by elim- 
 inating from an irreversible process one or more of its inevitable 
 accompaniments like friction or heat conduction. But reversible 
 (as well as irreversible) processes have common features. "They 
 resemble each other more than they do any one irreversible process. 
 This is evident from an examination of the differential equations 
 which control them; the differential with respect to time is always 
 of an even order, because the essential sign of time can be reversed. 
 Then too they (in whatever domain of physics they may lie) 
 have the common property that the Principle of Least Action 
 
 1 With the help of the preceding footnote this argument can be followed through 
 in detail for each of the cases enumerated on p. 31; only the complicated case of 
 diffusion presents any difficulty. 
 
36 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 can represent all of them completely and uniquely determines 
 the sequence of their events." They are useful for theoretical 
 demonstration and for the study of conditions of equilibrium. 
 
 There is a certain, limited, incomplete sense in which we say 
 that we can change from one state of equilibrium to another in 
 a reversible manner. For example, we can, considering only the 
 one converting (or intermediate) body, effect said change by a 
 successive use of isentropic and isothermal change. But this 
 ignores all but one of the participating bodies and this is not 
 permissible if we strictly adhere to the true definition of complete 
 reversible action. 
 
 We must remember too that no other universal measure of 
 irreversibility exists than entropy. "Dissipation" of energy has 
 been put forward as such a measure, but we know already of 
 two irreversible cases where there is no change of energy, namely, 
 diffusion and expansion of a gas into a vacuum. [Unavailable, 
 distributed, scattered energy are terms which could be used here, 
 free from all objection.] 
 
 But of course, the full equivalent of entropy can be substituted 
 as a universal measure of irreversibility. On p. 2 7 we have pointed 
 out that the number of complexions included in a given state can 
 be defined as the probability W of the state, then in a footnote, 
 attention is called to the identity of entropy with the logarithm 
 of this state of probability = logarithm of the number of complexions 
 of the state. This makes entropy a function of the number of 
 complexions, so that one may in this sense be regarded as the 
 equivalent of the other. We may now properly speak of the 
 number of complexions of a state as the universal measure of 
 its irreversibility. The physical meaning of irreversibility becomes 
 apparent when put in this form. The greater the number of com- 
 plexions included in a state the more disordered is its elementary 
 condition and the more difficult (more impossible, so to speak) , is 
 it to directly so influence the constituents of the whole that they 
 will reverse the sequence of the mean values the aggregate tends 
 
AND OF THE SECOND LAW 37 
 
 of itself to assume. An illustration will help to make this clear; 
 the irreversible case in which work (i.e., friction) is converted 
 into heat. " For example, the direct reversal of a frictional process 
 is impossible because this would presuppose the existence of an 
 elementary order among adjacent, mutually interacting molecules. 
 For then it must predominantly be the case that the collisions of 
 each pair of molecules must bear a certain distinguishable char- 
 acter inasmuch as the velocities of two colliding molecules must 
 always depend in a determinate manner on the place where they 
 meet. Only thereby can it be attained that there will result 
 from the collisions predominantly like directed velocities." 
 
 The outcome of the whole study of irreversibility results in 
 the briefly stated law : " There exists in Nature a quantity which 
 changes always in the same sense in all natural processes" 
 
 This boldly asserts the essential one-sidedness of Nature. 
 The proposition stated in this general form may be correct or 
 incorrect; but whichever it may be it will remain so independently 
 of human experimental skill. 
 
 SECTION D 
 
 (i) The Gradual Development of the Idea that Entropy Depends 
 
 on Probability 
 
 Entropy is difficult to conceive, in that, as it does not directly 
 affect the senses, there is nothing physical to represent it; it 
 cannot be felt like temperature. It has no analogue in the whole 
 of Physics; Zeuner's heat weight will perhaps serve as such for 
 reversible states, but is inadequate for irreversible ones. This 
 is not surprising when we consider the outcome, namely, that it 
 depends on probability considerations. 
 
 CLAUSIUS coined the term Entropy from the Greek, from a 
 word meaning transformation; with him the transformation value 
 was equal to the difference between the entropy of the final and 
 initial states. As there is a general expression for entropy, we 
 
38 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 can readily write the equivalent of any transformation between 
 two particular states. 
 
 Strictly speaking, however, entropy by itself depends only on 
 the state in question, not on any change it may experience, nor 
 on its past history before reaching the state contemplated. Of 
 course, this was appreciated by such a master mind as CLAUSIUS, 
 and, indeed, he defined the entropy as the algebraic sum of the 
 transformations necessary to bring a body into its existing state. 
 Moreover, as the formula for it was in terms of other more or 
 less sensible thermodynamic quantities, its relation to these was 
 at first more readily grasped, could be represented diagrammat- 
 ically, and had to do duty for the true, but still unknown, physical 
 idea of entropy itself. It was early understood, too, that growth 
 of entropy was closely connected with the degradation or waste 
 of energy; that it was identical with the Second Law. The fre- 
 quently given, but not always valid, relation, 
 
 dQ-TdS* 
 
 led to entropy being called a factor of energy. But all these 
 were change relations and did not go to the root of the difficulty, 
 as to what constituted the physical nature of unchanged entropy. 
 Quite early, too, there was a realization of the fact that 
 entropy had somehow a statistical character, that it had to do 
 with mean values only. This was well brought out by the long 
 known, and much quoted, " demon " experiment suggested by 
 Maxwell, in which a being of superhuman power separated, 
 without doing any work, the colder and hotter particles of a gas, 
 thus effecting an apparent violation of the Second Law. This, to 
 be sure, was getting close to the crux of the whole matter, but 
 still lacked much to give entropy a precise physical meaning. 
 Nevertheless, we see here a notable approach to the fundamental 
 
 1 This relation is not a valid one, unless the external work performed by a gas 
 during its change is equal to pdV. 
 
AND OF THE SECOND LAW 39 
 
 requirement that entropy must be tied down to the condition of 
 " elementary chaos " (elementare-unordnung). 
 
 We have already dwelt somewhat fully on this hypothesis of 
 " elementary chaos." 
 
 " It follows from this presentation that the concepts of entropy 
 and temperature in their essence are tied to the condition of 
 " elementare Unordnung." Thus a purely periodic absolute 
 plane wave possesses neither entropy nor temperature because 
 it contains nothing whatever in the way of uncheckable, non- 
 measurable magnitudes, and therefore cannot be " elementar- 
 ungeordnet," just as little as can be the case with the motion of 
 a single rigid atom. When there is [an irregular co-operation of 
 many partial oscillations of different periods, which independently 
 of each other propagate themselves in the different directions of 
 space, or] an irregular, confused, whirring intermingling of many 
 atoms, then (and not till then) is there furnished the preliminary 
 condition for the validity of the hypothesis of " elementare Unord- 
 nung and consequently for the existence of entropy and of 
 temperature." 
 
 " Now what mechanical or electro-dynamic magnitude repre- 
 sents the entropy of a state? Evidently this magnitude depends 
 m some way on the " Probability " of the state. For because 
 " elementare Unordnung " and the lack of every individual check 
 (or measurement) is of the essence of entropy it follows that only 
 combination or probability considerations can furnish the necessary 
 foothold for the computation of this magnitude. Even the 
 hypothesis of " elementare Unordnung " by itself is essentially 
 a proposition in Probability, for, out of a vast number of equally 
 possible cases, it selects a definite number and declares they do 
 not exist in Nature." 
 
 Now since the idea of entropy, and likewise the content of 
 Second Law, is a universal one, and since, moreover, the 
 theorems of probability possess no less universal significance, we 
 may conjecture (surmise) that the connection between Entropy 
 
-^ 40 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 and Probability will be a very close one. We therefore place 
 at the head (forefront) of our further presentation the following 
 proposition: " The Entropy of a physical system in a definite 
 condition depends solely on the probability of this state" The 
 permissibility and fruitfulness of this proposition will become 
 manifest later in different cases. A general and rigorous proof of 
 this proposition will not be attempted at this place. Indeed, 
 such an attempt would have no sense here because without a 
 numerical statement of the probability of a state it could not be 
 tested numerically. 
 . 
 
 (6) Planck's Formula for the Relation between Entropy and the 
 Number of Complexions 
 
 Now we have already seen, from the permutation consider- 
 ations presented on p. 27, that the Theory of Probabilities leads 
 very directly to the theorem, " The number of complexions included 
 in a given state constitutes the probability W of that state." The 
 next step (omitted here) is to identify the thermodynamically 
 found expression for entropy of any state with the logarithm 
 
 of its number of complexions. 
 
 - 1 
 
 PLANCK'S formula for entropy S is: 
 
 5 = 1.35 loge (number of complexions) io~ 16 + constant K; 
 
 here K is an arbitrary constant without physical significance 
 and can be omitted at pleasure; the numerical value in the first 
 term of the second member is the quotient of energy (expressed 
 in ergs) divided by temperature (C^. This certainly gives a phys- 
 -A* ical definiteness and precision to entropy which leaves nothing 
 to be desired. 
 
 PLANCK, in reproducing from probability consideration the 
 dependence of entropy 5 on probability W, finds the relation 
 
 5 = & log W + constant, 
 when the dimensions of 5 evidently depend on those of constant k. 
 
AND OF THE SECOND LAW 41 
 
 Here S is BOLTZMANN'S value H, wrn'ch always changes 
 in one direction only; k is the universal integration constant 
 which is the same for a terrestrial as for a cosmical system, and 
 when it is known for one, it is known for the other; when k is 
 known for radiant phenomena it is also known and is the same 
 for molecular motions. 
 
 There are some general statements which indicate more or 
 less rigorously some of the properties or features of the entropy 
 of a state. 
 
 (a) Entropy is a universal measure of the " disorder " in the 
 
 mass points of a system. 
 
 (b) Entropy is a universal measure of the irreversibility of a 
 
 state and is its criterion as well. 
 
 (c) Entropy is a universal measure of nature's preference for 
 
 the state. 
 
 (d) Entropy is a universal measure of the spontaneity with 
 
 which a state acts when it is free to change. 
 
 (e) Entropy of a system can only grow. 
 
 (f) Entropy asserts the essential one-sidedness of Nature. 
 
 (g) There exists in Nature a magnitude which always changes 
 
 in the same sense. 
 
 (e), (/), and (g) imply change and therefore, strictly speaking, 
 should not be mentioned here but postponed to a later section. 
 
 SECTION E 
 
 EQUIVALENTS OF CHANGE OF ENTROPY IN MORE OR LESS 
 GENERAL PHYSICAL TERMS 
 
 Here we are really considering the Second Law, for change 
 of entropy is the kernel of this law, in fact is identical with it. 
 It will be profitable, however, to view this law in all its many 
 physical aspects. To be sure, in times past it has been accounted 
 a reproach to the Second Law that it should be stated in so many 
 
42 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 different forms, 1 but now that we know precisely that it stands 
 for the growth in the number of complexions we can more easily 
 trace the connection between any of these rather vague state- 
 ments and the present precise definition. As we have in the 
 main reserved physical interpretations to a later section we 
 need here only bear in mind certain general principles of com- 
 parison : 
 
 Any complete summary of the premises necessary for estab- 
 lishing the inevitable growth of the number of complexions of 
 a system is a valid statement of the second law. 
 
 Any general corollary from said growth is a valid statement 
 of the second law. 
 
 When instituting any comparison we must keep in mind also 
 the two principal points of view of regarding any physical problem, 
 namely, the view of it in the aggregate and that which sees it in 
 its constituent parts. 
 
 While we cannot here sharply separate these two points of 
 view, we have on the whole sought to present first those statements 
 which are based on experience and next those based on the atomic 
 theory. 
 
 (1) Growth of entropy is a passage from more to less avail- 
 able energy. By available is here meant energy which 
 we can direct into any required channel. With the growth 
 in the number of complexions we can readily see there 
 is greater inability, on the part of the molecules, for that 
 concerted and co-operative action which is necessary for 
 the putting forth of the energy of a system. 
 
 (2) Growth of entropy is a passage from a concentrated to a 
 distributed condition of energy. Energy originally con- 
 centrated variously in the system is finally scattered uni- 
 
 1 This need cause no surprise, for it is only very recently that the conviction 
 is gaining ground that the Second Law has no independent significance, but that 
 its full content will only he grasped when its roots are sought in the Theorems of 
 the Calculus of Probabilities. 
 
AND OF THE SECOND LAW 43 
 
 formly in said system. In this aggregate aspect it is a 
 passage from variety to uniformity. 
 
 (3) Net growth of entropy in all bodies participating in an 
 occurrence means that the system as a whole has experienced 
 an irreversible change of state. This change is of course 
 in harmony with the first law of energy, but this growth 
 gives additional information as it indicates the direction 
 in which a natural process occurs. 
 
 (4) Growth of entropy is from less probable to more probable 
 states. 
 
 Growth of entropy is passage to a state more greatly preferred 
 
 by nature. 
 Growth of entropy is what obtains whenever a natural process 
 
 occurs " spontaneously." 
 
 f unsettled 1 
 Growth of entropy is a passage from j , . . Y to more 
 
 f settled 1 
 
 \ j. LI f conditions. 
 
 [ stable J 
 
 All these statements are conspicuously based on the theory 
 of probabilities. 
 
 (5) Growth of entropy is a passage from a somewhat regulated 
 to a less regulated state. It represents, in a certain sense, 
 Nature's escape from thralldom. 
 
 Growth of entropy is a passage from a somewhat ordered 
 
 to a less ordered molecular arrangement. 
 Growth of entropy is an increase in the disorder of a system 
 
 of mass points. 
 Growth of entropy corresponds to an increase in the number 
 
 of molecular complexions. 
 
 (6) Finally we give a mathematical concept which covers 
 the whole domain of physics: " Any function whose time 
 variation always has the same sign until a certain state 
 is reached and is then zero, may be called an entropy 
 function." 
 
44 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 SECTION F 
 MORE PRECISE AND SPECIFIC STATEMENTS OF THE SECOND LAW 
 
 We have here classified these statements in the same way as 
 that followed in the preceding section, when grouping the general 
 equivalents of the Second Law under the head of change of entropy. 
 In making comparisons we must, here as there, bear in mind the 
 following three helpful propositions : 
 
 (a) The summary of all the necessary prerequisites (or condi- 
 tions) for determining^ entropy may be regarded as a complete 
 and valid statement of the second law. 
 
 (b) Any general consequence of any one correct statement 
 of the second law may be regarded as itself a valid and complete 
 statement of the second law. 
 
 (c) All cases of irreversibility stand or fall together; if any 
 one of them can be completely reversed all can be so reversed. 
 
 In the preceding section we have already given the most 
 precise physical statement of the Second Law, namely, when all 
 the participating bodies of the system are considered, every 
 natural event is marked by an increase in the number of com- 
 plexions of the system. We have numbered the following state- 
 ments of the second law, for convenience of reference: 
 
 (1) J. W. GIBBS. "The imposliibility of an uncompensated 
 decrease in entropy seems to be reduced to an improbability." 
 This of course considers all the participating bodies of the 
 system. 
 
 (2) All changes in nature involve a net growth in entropy; 
 when such a change is measured in reversible ways, the growth 
 
 is indicated by the summation : I ^ o, when the \ , [ 
 
 sign refers to processes which on the whole are completely 
 
 {., , k Of course it is now thoroughly understood that 
 reversible ' 
 
AND OF THE SECOND LAW 45 
 
 the latter case is a purely ideal one, which is really never realized 
 in nature and is only a convenient and fruitful fiction in theoretical 
 demonstrations. 
 
 (3) M. PLANCK. " It is not possible to construct a periodically 
 functioning motor which effects nothing more that the lifting 
 of a load and the cooling of a heat reservoir." 
 
 The proof of this is purely experimental and cumulative 
 and in this respect is exactly like that for the First Law, the Con- 
 servation of Energy, and has exactly the same sort of validity. 
 
 (4) Perpetual motion of an isolated system, such as a mechan- 
 ism with friction, is impossible and not even approximately real- 
 izable. 
 
 This refers to perpetual motion of the second class, a clear 
 illustration of which is given on p. 8 of Goodenough's Notes on 
 Thermodynamics: "A mechanism with friction is inclosed in 
 a case through which no energy passes. Let the mechanism be 
 started in motion. Because of friction work is converted into 
 heat which remains in the system, since no energy passes through 
 the case. Suppose that the heat thus produced could be completely 
 transformed into work; then this work would be used again to 
 overcome friction and the heat thus produced would be again 
 transformed into work. We should then have perpetual motion 
 in a mechanism with friction without the addition of energy 
 from an external source." This can be shown to be equivalent 
 but not identical with the " perpetual motion of the second kind," 
 touched upon in p. 30; the latter does confessedly draw on 
 external energy and furnishes a surplus of power for use, say, in 
 technical service. 
 
 Nominally, such a machine is a case of perpetual motion, but 
 not in the usually accepted sense, for it furnishes no surplus of 
 power; it is the getting of something for nothing, of getting cost- 
 free power, which has always been the attractive feature of so-called 
 perpetual motion. Still this machine is as much at variance 
 with experience as PLANCK'S perpetually working motor of the 
 
7 
 
 46 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 second kind. The former may be readily reduced to the latter, 
 for it is easy to conceive of such legitimate modification of the 
 former as will make it only a special case of the latter. 
 
 (5) The following statements are by distinguished physicists 
 and had better here be considered as confined to events occurring 
 in closed cycles. 
 
 CLAUSIUS. It is impossible for a self-acting machine unaided 
 by any external agency to convey heat from one body to another 
 of higher temperature. 
 
 CLERK MAXWELL. It is impossible by the unaided action of 
 $ natural processes to transform any part of the heat of a body 
 into mechanical work, except by allowing heat to pass from that 
 body to another of lower temperature. 
 
 THOMSON. It is impossible by means of inanimate material 
 agency to derive mechanical effect from any portion of matter 
 by cooling it below the temperature of the coldest of surrounding 
 objects. 
 
 (6) The efficiency of a perfect engine is independent of the 
 working fluid. 
 
 (7) Waste of energy once incurred cannot be diminished in 
 the universe, or in any part of it which neither takes in nor gives 
 out energy. 
 
 We understand here by waste that residual part of heat of 
 which none can be elevated back into work. 
 
 The measure of such ^waste = To(S 2 Si), when TO = lowest 
 temperature and S 2 Si = change of entropy in a process. This 
 brings out emphatically that the Second Law is not a law of con- 
 servation, it is a law of waste, a law of wasted opportunities for 
 utilizing technically available energy. 
 
 (8) The second law and irreversibility do not depend on any 
 special peculiarity of heat motion, but only on the statistical 
 property of a system possessing an extraordinary number of 
 degrees of freedom. 
 
 (9) M. PLANCK. The second law, in its objective physical 
 
AND OF THE SECOND LAW 47 
 
 form (freed from all anthropomorphism) refers to certain mean 
 values which are formed from a great number of like " chaotic " 
 elements. 
 
 (10) When all the participating bodies of the system are 
 considered, every natural event is marked by an increase in the 
 number of complexions of the system. We repeat, this is the 
 most precise physical statement of the second law and covers the 
 whole domain of science. 
 
 We will not comment further on these statements at this time, 
 leaving such discussion of their relations to the section on physical 
 interpretations. 
 
48 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 PART II 
 
 ANALYTICAL EXPRESSIONS FOR A FEW PRIMARY RELATIONS 
 
 AT the beginning of this presentation we disclaimed any pur- 
 pose of giving a rigorous proof for any of the many formulas 
 with which this subject bristles. We propose only to give in some 
 cases an outline of the main steps of the demonstration and 
 merely for the purpose of getting a clearer physical insight into 
 certain states and relations. Pre-eminent in importance is the 
 state of thermal equilibrium (see pp. 19, 52, 53) and we will 
 therefore consider first its main characteristic: 
 
 SECTION A 
 MAXWELL'S LAW OF DISTRIBUTION OF MOLECULAR VELOCITIES 
 
 Without giving a full proof of the law we will give the main 
 steps which lead to its analytical statement, in so doing following 
 the presentation given by HANS LORENZ on pp. 526-529 of his 
 " Technische Warmelehiie," and will then point out its main 
 features and consequences. 
 
 We suppose the gas to contain in a unit of volume n molecules 
 each possessing a different velocity and direction. Let there be 
 a system of three co-ordinate axes, , 77, . A fraction f()d 
 of the total number of molecules will possess a velocity in the 
 direction, whose values lie between and + d. The number 
 of molecules which at the same time possess velocities in the T? 
 direction, lying between TJ and y+dy, will be nf()df(r))dt), 
 since no preference can be given to either the or r) direction. 
 Similarly and finally the number of molecules whose velocity 
 
AND OF THE SECOND LAW 49 
 
 co-ordinates concurrently lie between , 77, , and +</, 
 will be represented by the product 
 
 where the only thing known about function / is that the sum of 
 the fractions f()dg extended over all the values of must = unity, 
 so that 
 
 Now if we suppose all of the velocities of the n molecules to 
 be laid off as vectors from a pole O, the three directions , 9, 
 will constitute about O a perfectly arbitrary system of co-ordi- 
 nates in which (d) (dy) (dV)=dV designates a volume element l 
 and the velocity p of a molecule is given by 
 
 1 In MAXWELL'S distribution the molecules are assumed to be uniformly scat- 
 terred throughout the unit volume; it is the velocities only that are variously 
 distributed in the different elementary regions. To realize the haphazard char- 
 acter (necessary in Calculus of Probabilities) of the motions of the molecules, we 
 must bear in mind that each of the molecules in the unit volume has a different 
 velocity and direction; here no direction has preference over another, i.e., one direc- 
 tion of a molecule is as likely as another. Here at first we write expression for 
 the number of molecules whose velocities parallel to the co-ordinate axes are 
 respectively confined between the velocity limits: 
 
 and 
 T) and 
 
 C and 
 
 To find the number of molecules thus limited the procedure given above isessentially 
 as follows: Expressed as a, fraction f()d= probability of velocities parallel to 
 axis having values between and + d and expressed as a number nf()d= 
 number of molecules having such velocities between the assigned limits; similarly, 
 f(rj)dr)= probability of velocities parallel to TJ axis having velocities between TJ and 
 ij+di). As these are two independent sets of velocities, the probability of their 
 concurrence is the product f()d-f(i))di) and the number of molecules thus con- 
 
50 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 Now if we put through the origin O another system of co-ordi- 
 nates of which one axis coincides with any arbitrarily chosen 
 velocity p, then in this axis the above-found product will be 
 nf(p)f(O) -f(O)dV because the two other co-ordinates (outside 
 of p) of the volume element dV will equal zero and no preference 
 can be given to any direction. Then it can be shown that the 
 form of the function is given by 
 
 _i! 
 
 Ce <V (3) 
 
 where C, c are integration constants which stand in a certain 
 relation to each other, namely, 
 
 C = ~^. (4) 
 
 Further mathematical manipulation eliminates the different 
 velocity directions and gives 
 
 , ... (5) 
 
 for the number of molecules possessing absolute velocities between 
 p and p-\-dp. 
 
 This expression (5) is called MAXWELL'S Law of Distribution; 
 it is identical with that found for the probable distribution of 
 'error in a great number of observations and is graphically shown 
 by the following figure, with maximum number of molecules for 
 velocity c. The constant c is therefore a velocity from which 
 
 curring is equal to nf()d -f(TJ)d. Similarly, the number of molecules concurrently 
 possessing velocities parallel to each of the three axes is 
 
 The problem is simpler in this Maxwellian case than in the more general case of 
 any state of the body in which there is an unequal distribution in space of the 
 molecules. 
 
AND OF THE SECOND LAW 
 
 51 
 
 most of the molecules differ but little. The development shows 
 that this self-same distribution exists for every straight line that 
 can be drawn in the volume under consideration. 
 
 3 5 
 
 if 
 
 
 
 E = 
 
 Velocities. ' 
 
 BOLTZMANN, in his Gas Theorie, has shown that for such a 
 state the " number of complexions " is a maximum, that is, the 
 entropy is then a maximum. 
 
 From the preceeding expression (5) follows that the kinetic 
 energy U of the system is 
 
 U 
 
 where [w 2 ] is the mean square of the velocity. Integration gives 
 
 f* (7) 
 
 It is known that the measure of temperature is the mean kinetic 
 energy of the individual molecule and not simply the mean square 
 of its velocity, and we possess here therefore a perfectly precise 
 
52 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 definition of temperature. We see also from (7) that temperature 
 in a particular gas is directly proportional to either c 2 or [w 2 ]. 
 
 MAXWELL further shows without any assumption as to the 
 nature of the molecules, or the forces acting between them, that 
 the derived law of distribution is valid for any gas mixture, but 
 that is it modified when the gas is exposed to the action of external 
 forces. 
 
 BOLTZMANN found (Wien. Akad. Sitzber. LXXII B, 1875, p. 
 443) for monatomic gases that in spite of the effect of external 
 forces (a) the velocity of any molecule is equally likely to have 
 any direction whatever, (b) the velocity distribution in any element 
 of space is exactly like that in a gas of equal density and temperature 
 upon which no external forces act, the effect of the external forces 
 consisting only in varying the density from place to place as in 
 hydrodynamics. 
 
 BOLTZMANN says this " normal " state is permanent (stationary) 
 for given external conditions because magnitude H does not 
 vary; such a normal state has many configurations, but all agree 
 in having same number of complexions. 
 
 Also, " MAXWELL'S Velocity Distribution is not a state which 
 assigns to each molecule a particular place (locus) and a particular 
 velocity, which are reached say by the locus and velocity of each 
 molecule asymptotically approaching said assigned locus and 
 velocity. With & finite number of molecules MAXWELL'S state will 
 never be exactly but only approximately realized. MAXWELL'S 
 velocity is not a singular one which is confronted by an immense 
 number of non-Maxwellian velocity distributions. On the con- 
 trary, among the immense number of possible velocity distributions 
 by far the greater number possess the characteristics of the 
 MAXWELL velocity distribution." 
 
 MAX PLANCK (Festschrift, p. 113) lucidly dwells on thermal 
 equilibrium, entropy and temperature, as follows: 
 
 " The mechanical significance of the temperature idea is 
 most closely connected with the mechanical significance of entropy, 
 
AND OF THE SECOND LAW 53 
 
 for the two are connected by TdS=dQ. By answering one of 
 these questions we at the same time settle the other." 
 
 In the earlier days interest was naturally centered in the 
 directly measurable magnitude temperature and entropy appeared 
 as a more complicated idea which was to be derived from the 
 former. Nowadays this relation is rather reversed and the prime 
 question is to first explain entropy mechanically and this will 
 then define temperature. The reason for this change of attitude 
 is that in all such explanatory efforts to present Thermodynamics 
 mechanically and give temperature a complete mechanical definition 
 it is necessary to come back to the peculiarities of " thermal equi- 
 librium." But the full significance of this equilibrium conception 
 is. only to be reached from the standpoint of irreversibility. For 
 thermal equilibrium can only be defined as the final state toward 
 which all irreversible processes strive. Tn this way the question 
 as to temperature leads necessarily to the nature of irreversibility 
 and this in turn is solely founded on the existence of the entropy 
 function. This magnitude is therefore the primary, general 
 conception which is significant for all kinds of states and changes 
 of state, while temperature emerges from this with the help of 
 the special condition of thermal equilibrium, in which condition 
 the entropy attains its maximum. 
 
 SECTION B 
 
 SIMPLE ANALYTICAL EXPRESSION FOR DEPENDENCE OF ENTROPY 
 
 ON PROBABLITY 
 
 Here also we will dispense with a full proof and content our- 
 selves with the main steps which lead to the desired expression. 
 We will follow PLANCK'S elegant presentation on pp. 136-148 of 
 his Warmestrahlung. On p. 22 we have dwelt on the usefulness 
 and the necessity for the probability idea in general physics and 
 in this particular case. We can start, therefore, with PLANCK'S 
 theorem : 
 
54 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 " The entropy of a physical system in a particular state depends 
 solely on the probablity of this state." 
 
 No rigorous proof is here attempted, nor any numerical com- 
 putations; for present purposes it will suffice to fix in a general 
 way the kind of dependence of entropy on probability. 
 
 Let S designate the entropy and W the probability of a 
 physical system in a particular state, then the above theorem 
 enunciates that 
 
 S=f(W), ........ (8) 
 
 where f(W) signifies a universal function of the argument W. 
 Now, however W may be defined we can certainly infer from the 
 Calculus of Probabilities that the probability of a system, com- 
 posed of two entirely independent systems, is equal to the product 
 of the separate probabilities of the individual systems. For 
 example, if we take for the first sys^n any terrestrial body what- 
 ever and for the second system any hollow space on Sirius, which 
 is traversed by radiations, then the probability W, that simultane- 
 ously the terrestrial body will be in a particular state i and said 
 radiation in a particular state 2, will be given by 
 
 (9) 
 
 where Wi, W 2 respectively represent the separate probabilities 
 of said two states. Now let Si, S 2 respectively represent the 
 entropies of the separate systems corresponding to said states 
 i and 2, then according to Eq. 8, we have 
 
 Si=/OFi), S 2 =f(W 2 ). 
 
 But, according to the Second Law of Thermodynamics, the total 
 entropy of two independent systems is 5=6*1+52, and conse- 
 quently according to (8) and (9), 
 
 ^ 
 
AND OF THE SECOND LAW 55 
 
 From this functional' equation / may be determined. After 
 successive differentiation there is obtained a differential equation 
 of the second order and its general integral is 
 
 f(W) =k log W+ constant 
 or S=k log W+ constant, .... (10) 
 
 which determines the general dependence of entropy on proba- 
 bility. The universal integration constant k is the same for a 
 terrestrial system as for a cosmical system, and when its numerical 
 value is known for either system it will be known for the other; 
 indeed, this constant k is the same for physically unlike systems, 
 as above, where concurrence between a molecular and a radiating 
 system was assumed. The last, additive, constant has no physical 
 significance because entropy has an arbitrary additive constant 
 and therefore this constant in (10) may be omitted at pleasure. 
 
 Relation (10) contains a general method of computing the 
 entropy S from probability considerations. But the relation 
 becomes of practical value only when the magnitude W of the 
 probability of a system for a certain state can be given numerically. 
 The most general and precise definition of this magnitude is an 
 important physical problem and first of all demands closer insight 
 into the details of what constitutes the " state " of a physical system. 
 [This has been adequately done in the earlier part of this presen- 
 tation. Later on pp. 27, 28, permutation considerations led us 
 to define the probability IF of a state as the number of com- 
 plexions included in the given state.] 
 
56 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 SECTION C 
 
 DETERMINATION OF A PRECISE, NUMERICAL, EXPRESSION FOR THE 
 ENTROPY OF ANY PHYSICAL CONFIGURATION 
 
 PLANCK modestly says that everything essential in the deter- 
 mination of this expression has been done by L. BOLTZMANN, in 
 his wide range of physical investigation. PLANCK'S discussion, 
 however, is so compact and lucid that it is best suited for our 
 purpose. Keeping this purpose in mind we will here also abbre- 
 viate by dispensing with parts of PLANCK'S fuller proof and content 
 ourselves with the main steps which lead to the desired expression. 
 These main steps are as follows: 
 
 (a) Determination of the general expression for the 
 
 f Probability or 1 
 
 \ XT . . . TT7 \ of a given physical configuration of 
 
 [ No. of complexions W J 
 
 a known macroscopic state; 
 
 (b) Determination of the general expression for the Entropy 5 
 of a given physical configuration of a known macroscopic 
 state; 
 
 (c) Special case of (b) namely, expression for the Entropy 5 of 
 the state of thermal equilibrium of a monatomic gas; 
 
 (d) Confirmation, by equating this value of S with that found 
 thermodynamically and then deriving well-known results. 
 
 (e) PLANCK'S conversion of the expressions of (b) and (c) into 
 more precise ones by finding numerical values of k 
 in C. G. S. units; in F. P. S. units; 
 
 (f) Determination of the dimensions of the universal constant k 
 and therefore also of entropy in general. 
 
AND OF THE SECOND LAW 57 
 
 Step a 
 
 Determination of the Number of Complexions of a given Physical 
 Configuration of a Known Macrostate 
 
 We will, for simplicity's sake, consider here an ideal gas in a 
 given macrostate and consisting of TV-like, monatomic, molecules. 
 By generalizing the meaning of our co-ordinates, the following 
 presentation could be made equally applicable to the more general 
 case of Physics contemplated under this heading. 
 
 Of course we must here have clearly in mind what is meant 
 by the state of a gas. For this we may refer to p. 10 (lines 13 to 24) 
 and to p. 19 (lines 8 to 24). The conditions there imposed 
 are all fulfilled if we suppose the state given in such a way that 
 we know: (i) The number of molecules in any macroscopically 
 small space (volume element); and (2) the number of molecules 
 which lie in a certain macroscopically small velocity region (soon 
 to be more fully described). To have the Calculus of Probabilities 
 applicable, each of the tiny regions contemplated under (i) and (2) 
 must still contain a large number of molecules and their motions 
 must besides have all the features of haphazard detailed on pp. 
 25, 26; all this is necessary in order that the contemplated 
 motions may possess all the characteristics of " elementary chaos." 
 
 Before proceeding further on our main line, we will define 
 more fully what is meant by the two elementary regions in which 
 lie respectively the molecules and their velocity ends. After 
 this has been done we will, for convenience, combine these two 
 regions into a fictitious elementary region, say, a six-dimensional 
 one. 
 
 First there is the volume element dx-dy-dz^dV, in which 
 
 (x and x + dx T 
 y and y + dy \ 
 z and z + dz J 
 is located; this element can be conceived as a parallelopipedon 
 
58 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 whose edges are parallel to the co-ordinate axes ; this is the simplest 
 of the elementary regions here to be considered. To conceive 
 of the elementary region ds-dy-d^ containing the velocity ends of 
 the molecules, let us suppose any origin O for velocities in a unit 
 volume and from this as a pole lay off as vectors the molecular 
 velocities lying between the limits, 
 
 and 
 
 and Tj+dy, ...... (n) 
 
 and ^ 
 
 where , ij, are the components of said velocities parallel to the 
 respective co-ordinate axes. Then, under the velocity limitations 
 imposed, the end of the velocity of each such molecule will lie in 
 the elementary parallelepiped dZ-dy-d^, one vertex of this 
 parallelepiped having of course the co-ordinates , y, . This 
 parallelepiped can be regarded as a constructed volume within 
 which the velocity end must lie. We have therefore here two 
 elementary volumes dx-dy- dz and d^-dy-d^ which are independent 
 of each other,. Now remembering that the probability of any 
 properly endowed molecule being found in one of these volumes 
 is in each case equal to the number of molecules belonging or 
 corresponding to the volume considered. Assuming, for the 
 moment, an equal distribution of molecules and velocities through- 
 out the whole volume, we may say that the number of molecules 
 occurring, in each of the said elementary volumes, is proportional 
 to their respective sizes; this is here equivalent to saying that 
 the probability of any molecule thus occurring in said elementary 
 volumes is proportional to their respective sizes. Having stated 
 the probability of each contemplated occurrence, we can now say 
 the probability of these two events concurring is equal to the product 
 of the probabilities of said two separate occurrences. Moreover, 
 as the probability of each occurrence is proportional to the size 
 
AND OF THE SECOND LAW 59 
 
 of its own elementary volume, the product of said probabilities 
 will likewise be proportional to the product 
 
 dx-dy-dz-dZ-drj-d^^a (12) 
 
 of the two elementary volumes. Here a can be regarded as a sort 
 of fictitious volume or region, constructed, say, in a six-dimensional 
 space. 1 
 
 The extent of such an elementary region is very minute in 
 comparison with the total space under consideration, but still 
 it must be conceived as sufficiently large to embrace many mole- 
 cules, otherwise its state would not be one of " elementary chaos." 
 On account of the equivalence here of probability and number 
 of concurring molecules, we may for the present say that the 
 number of the latter is proportional to the magnitude of this 
 elementary region a. But before we proceed further this last 
 statement must be subjected to a correction, for we temporarily 
 assumed above that there was an equal distribution of molecules 
 and velocities throughout the whole volume. Now at the start, 
 in defining the contemplated state, it was distinctly announced 
 that there was an unequal distribution of such elementary con- 
 ditions, the law of their distribution being given by the known 
 number of molecules in each elementary volume dV and in each 
 constructed elementary velocity volume d^-dy-d^. This correction 
 is effected by the introduction of a finite proportionality factor, 
 
 /(*,?,,, 7, Q, ...... (13) 
 
 which can be any given function of the location and velocity 
 co-ordinates, so long as it fulfills the one condition (put in abbre- 
 viated form), 
 
 S/-<T = ,V, (14) 
 
 where N = the total number of molecules of the gas. 
 
 1 Such a fictitious space does not occur in the proof of MAXWELL'S distribution, 
 because there conditions are simpler. See foot-note to p. 49. 
 
60 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 Strictly speaking, the expression a for the fictitious elementary 
 region a, formed by the product of dV and the constructed- 
 volume element dZ-dy-d^, should be replaced by the expression 
 m 3 a, where m is the mass of a molecule. The reason for this 
 substitution is found in the fact that the magnitude of the con- 
 structed-volume element dZ-dy-dt, varies with time due to the 
 variation of velocities effected by molecular collisions. Now 
 this variation of magnitude is not permissible with the probability 
 considerations which here obtain. For the probability of a state 
 which necessarily follows from another state must be like that 
 of the latter. As the momenta after collision are the same as 
 before collision, we have now in the momenta, co-ordinates which 
 do not vary with time like their constituent velocities. Therefore 
 if we substitute in (12) for the velocities , >?, their corresponding 
 momenta, the variation with time of the constructed-volume will 
 cease and the objection cited will no longer be a valid one. 
 
 Now let us take up the determination of the number of com- 
 plexions W in the given state. For this purpose think of this 
 whole state as represented by the sum total of all these equal 
 elementary regions m z a\ for convenience of reference let us call 
 this whole state the " state-region." The probability that a par- 
 ticular molecule will belong to a particular elementary region 
 is equally great for all the elementary regions. Let P represent 
 the number of these equal elementary regions. Now we will 
 proceed with the help of a parallel case. Let us think of as many 
 dice N as there are molecules and let each die be provided with 
 P faces. On each of these faces we will write in their order the 
 digits i, 2, 3, . . . P, so that each of the P faces will designate 
 a particular elementary region. Then each throw of the N 
 dice will result in representing a particular state of the gas, because 
 the number of dice which show uppermost a particular digit 
 will give the number of molecules belonging to the elementary 
 region represented by said digit. In this parallel case each die is 
 equally likely to show up any one of the digits i to P, corresponding 
 
AND OF THE SECOND LAW 61 
 
 i 
 
 to the circumstance that each individual molecule is equally 
 likely to belong to any one of the elementary regions. The 
 desired probability W of the given state of the molecules corre- 
 sponds therefore to the number of different kinds of throws (com- 
 plexions), by which the given distribution / can be realized. 
 For example, if we take N=io molecules (dice) and P = 6 
 elementary regions (dice faces), and assume that the state is so 
 given that it is represented by: 
 
 3 molecules in elementary region i 
 
 4 " " " 2 
 
 " " " 3 
 
 1 ll " " 4 
 o " " " 5 
 
 2 " " " 6 
 
 Then this state can be realized by one throw, in which the 10 
 dice show the following digits : 
 
 ist ad 3d 4th sth 6th ?th 8th gth loth die 
 
 the 2621126214 digit (15) 
 
 Under each of the 10 dice stands the digit shown uppermost 
 in the throw. In fact, we see 
 
 3 dice with digit i 
 
 4 " " 2 
 
 " " 3 
 
 1 " 4 
 o " " 5 
 
 2 6 
 
 In like manner the same state can be realized by many other 
 such complexions. The desired number of all possible complex- 
 ions can be found by considering the digit row designated above 
 by (15). For, since the number of molecules (dice) is given, 
 
62 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 the digit row will have a particular number of places (io = .ZV). 
 Besides, since the number of molecules belonging to each elemen- 
 tary space is given, each digit will occur equally often in the row 
 in all permissible complexions. Moreover every change in digit 
 arrangement effects a new complexion. The number of the 
 possible complexions or the probability W of the given state is 
 therefore equal, under the conditions specified, to the possible 
 " permutations with repetition." 1 In the simple example chosen 
 we have for such permutation, according to a known formula, 
 
 10! 
 
 12,600. 
 
 3! 4! o! i ! o! 2 
 Consequently in the general case, we have 
 
 N\ 
 
 where the sign n signifies the product extended over all the P 
 elementary regions. 
 
 Result contained in (16) is equally true for any other physical 
 system, say, one involving radiant energy. For the conditions 
 and the variables are similar to those of the molecular system 
 just employed. The chosen model, the dice system, which served 
 as an easily conceived parallel case, would be equally serviceable 
 in dealing with the elements of radiation. 
 
 1 Compare with pp. 27 and 28 where this permutation process is discussed some- 
 what fully. 
 
AND OF THE SECOND LAW 63 
 
 Step b 
 
 Determination of a General Expression for the Entropy S of any 
 given Natural State 
 
 This step is an easy one. We have in Eq. (10) the relation 
 expressing the universal dependence of entropy S on probability 
 W. Substituting and writing out the logarithm of the quotient 
 given in (16), we have 
 
 S = HogAn-Slog(/.<7)!. .... (17) 
 
 The summation S must be extended over all the elementary 
 regions a. With the help of STIRLING'S formula, and remembering 
 that both o and N=^f-a are constant for all changes of state, 
 the above expression (17) is reduced to the form 
 
 Entropy 5= constant /-log/-<7. . . ... (18) 
 
 This magnitude 5 is numerically the same as H for which BOLTZ- 
 MANN proved that it changed in a one-sided way in all changes 
 of state. We must bear in mind too that function / represents, 
 for every state of the gas, the given space and velocity distribution 
 of the gas molecules. The permanent, stationary, state of the 
 gas known as thermal equilibrium is only a special case of the 
 general case (18), this special case being widely known as MAX- 
 WELL'S Law of Distribution of Velocities. 
 
 Step c 
 
 Special Case of (b), Namely, Determination of Entropy S for the 
 Thermal Equilibrium of a Monatomic Gas 
 
 This case PLANCK derives very easily from the general case 
 represented by (18). As the desired result has already been 
 found in another way in pp. 48-53 when dealing with MAXWELL'S 
 
64 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 Law (of distribution of molecular velocities), we will not repeat 
 PLANCK'S derivation of the law from (18). It will suffice here to 
 give the results: The law of distribution is given by function 
 
 where a and /? are constants and U the total energy. As this expres- 
 sion for function/is free from all location co-ordinates x, y, z, we see 
 that this state of thermal equilibrium is independent of these 
 space co-ordinates and conclude that in this state the molecules 
 are uniformly distributed in space; only the velocities are variously 
 distributed, all of which accords with the earlier presentation. 
 Substituting the results of (19) in the general equation (18) there 
 results for the entropy 5 of the state of equilibrium of a monatomic 
 
 as ' S = constant + kN($ log U+logV). . . . (20) 
 
 To make Eq. (20) practically serviceable we need to know the 
 constants k and N and they will be found later on. 
 
 Step d 
 
 Confirmation, by Equating this Probability Value of S with that 
 found Thermodynamically and Securing well-known Results 
 
 We know from Thermodynamics that the change of entropy 
 is denned in a perfectly general way (for physical changes) 1 by 
 
 __ dU + pdV 
 dS = ^ - ....... (21) 
 
 Deriving the partial differential coefficients and making use 
 of (20), there follows: kNT RnT 
 
 P=y-=~> ...... (22) 
 
 1 This differential equation is valid only for changes of temperature and volume 
 of the body but not for its changes of mass and of chemical composition, for in 
 in defining entropy nothing was said of these latter changes. 
 
AND OF THE SECOND LAW 65 
 
 where n= number of gram-molecules (referred to O 2 =32g) and 
 
 erg 
 R =8.315 (io 7 ) -7 = absolute gas constant [1545 in F.P.S. system] 
 
 Here the first of Eqs. (22), represents the combined laws of BOYLE, 
 GAY-LUSSAC, and AVOGADRO. We get besides from the equating 
 of (20) and (21), the additional relations, 
 
 (23) 
 
 where mechanical equivalent A =4.i9(io 5 ) p C.G.S. system. 
 From this follows 
 
 ^=3-i C P = $> and ^ = 7, ( 2 4) 
 
 c v 3 
 
 as is known for monatomic gases. 
 
 Furthermore, we find for the mean kinetic energy L of a 
 molecule 
 
 L = ~=^-kT. (25) 
 
 N 2 
 
 We also have 
 
 n w wt. of a molecule 
 
 &=-= = = const, for all gases. (26) 
 
 N m molecular wt. of a molecule 
 
 With the help of the specific heats and the characteristic equation 
 of the gas, the whole thermodynamic behavior of the gas is disclosed. 
 All this has resulted from the ^identification of the mechanical and 
 thermodynamic expressions for entropy and is an indication of 
 the fruitfulness of the method pursued. PLANCK also shows that 
 this method leads to the finding of results heretofore unknown. 
 
66 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 Step e 
 
 Conversion of the General Expressions in (b) and (c) info more 
 Precise ones by Finding and Inserting the Numerical Value oj 
 the Universal Constant k ; Some of the Results 
 
 From the consideration of certain phenomena of radiation 
 PLANCK found 
 
 erg 
 
 ~ 16 * absolute c G - s - 
 
 " in F - P - S * 
 
 where a and b are constants found by experiment while a and ft 
 are exactly known values, mathematically derived. The present 
 accuracy of (27) therefore rests on the accuracy of the experiments 
 from which a and b were found. In discussing Eq. (10) it was 
 pointed out that k was a universal constant, applicable to all 
 physical systems and consequently may be used for the molecular 
 configurations mainly considered in this presentation. But before 
 introducing numerical value of k in the general expressions con- 
 tained under headings b and c, we will add other numerical 
 values of interest. 
 
 PLANCK gives 2.76(io 19 ) =number of molecules in i ccm. of an 
 ideal gas at freezing-point (o C.) and atmospheric pressure; 
 
 N 
 he also gives for the ratio =6.i75(io 23 ) =number of molecules 
 
 per m grams; the corresponding numbers in English units are, 
 approximately, 782 (zo 23 ) = number of molecules in one cubic foot 
 
 J N 2.80(I0 2 6) 
 
 of an ideal gas and = - = number of molecules in one 
 n m 
 
 pound of an ideal gas. Assuming air to be an ideal gas and its 
 " apparent " molecular weight about 28.88, the number of mole- 
 
AND OF THE SECOND LAW 67 
 
 2.8o 
 cules in one pound of air would be (lo 26 ) =o.g7(io 25 ). 
 
 Substituting the numerical value of universal constant k in 
 Eq. (10) we get Eq. (28). 
 For C. G. S. system, Entropy of any natural state, Eq. (28) is 
 
 5 = i.346(io~ 16 ) loge (W) = i. 346(10 ~ 16 ) loge (No. of complexions). 
 For F. P. S. system, Entropy of any natural state, Eq. (28) is 
 5 = 5.5o(io~ 24 ) log e (W) =5.5o(io~ 24 ) loge (No. of complexions.) 
 
 To each of these may be added an arbitrary constant. In 
 Eq. (20) we may substitute directly the equivalent of the product 
 kN found from Eq. (22), and then get for the entropy S of a 
 monatomic gas in the state of thermal equilibrium, 
 
 (29) 
 
 When the volume V is known we can now readily find N 
 and then kN numerically, and place this number as a coefficient 
 in Eq. (20). 
 
 Stepf 
 Determination of the Dimensions of k or of the Entropy S 
 
 It is at once evident from an inspection of the perfectly general 
 Eq. (10) that the dimensions of Entropy 5 depend solely on those 
 of the universal constant k. The relation given in Eq. (21) shows 
 at once that dimensions of dS depend upon the quotient found 
 by dividing energy by temperature and the relations given in 
 Eqs. (22) and (25) that the dimensions of constant k also depend 
 on this same quotient. The dimensions of Entropy S and of con- 
 stant k are therefore identical and this might suffice to show that 
 here neither S nor k is to be regarded as a mere ratio or abstract 
 
68 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 number. A word further in this connection may, however, be 
 helpful. In reversible processes we have the well-known relation 
 dQ = TdS. To simplify matters, let us suppose heat dQ supplied 
 while volume is kept constant, then dQ = c v dT= TdS or 
 
 ^=^r'. * ..... (30) 
 
 Here Entropy S has the same dimensions as c v ; now in the 
 relation dQ = cjlT if we regard c v as an abstract number then, 
 in order that the equation shall be homogeneous the factor (dT) 
 must represent heat energy like dQ, and this is sometimes done; 
 
 7/T1 
 
 hi such case (if T retains its ordinary meaning) the quotient -=7 
 
 in Eq. (30) is no longer a mere ratio or abstract number, but a 
 quotient of the dimensions of energy divided by temperature. 
 
 dQ 
 On the other hand, if c v=jf be regarded as of the dimensions 
 
 of the quotient of energy divided by temperature, then we may 
 
 /IT* 
 
 consider -~ in (30) as an abstract number or ratio and dS of the 
 
 same dimensions as C v . When an absolute system of units is 
 employed, which possesses as one of its features the expression of 
 temperature in units of energy, then k, S and c v will all be mere 
 ratios or abstract numbers. 1 
 
 iSee C. V, BURTON'S article in Philosophical Transactions, Vol. 23-24, 1887. 
 
AND OF THE SECOND LAW 69 
 
 PART III 
 
 PHYSICAL INTERPRETATIONS 
 SECTION A 
 
 OF THE SIMPLE REVERSIBLE OPERATIONS IN THERMODYNAMICS 
 
 Change under Constant Volume 
 
 WE found above that the entropy of a state was precisely 
 defined in a physical way by the number of complexions of that 
 state. Now let us see what happens to this number of com- 
 plexions when an ideal gas experiences some of the simpler 
 changes, of a reversible (non-cyclical) character. We will begin 
 with the case in which the volume of the gas remains constant 
 while its temperature rises, the final state of the gas having a 
 higher temperature than its initial state. 
 
 We see from Eq. (7), p. 51, that c grows and from Eq. (4), 
 p. 50, that C diminishes. MAXWELL'S Law, given by Eq. (5), 
 
 p. 50, shows for a given velocity that the number -r- of molecules 
 
 c ap 
 
 possessing the given velocity is less in the final state than it was 
 in the initial state, and as the total number n of molecules in the 
 gas is unchanged, there will be a greater variety of velocities in 
 the final state. This makes the number of possible permutations 
 greater in the final state, thus increasing the number of com- 
 plexions; consequently, as entropy varies with the logarithm of 
 the number of complexions, we see that the entropy of the final 
 state is greater than in the initial state and this agrees with 
 experience. 
 
70 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 Isobaric Change 
 
 Next we interpret how the number of complexions are affected 
 by isobaric change during a reversible process, again assuming 
 that the temperature in the final state is greater than in the 
 initial one. Here the steps and the conclusion are exactly the 
 same as in the preceding case. In both cases just the opposite 
 result is reached when there is a fall in temperature. 
 
 As the pv diagram contains the co-ordinates p, v, and repre- 
 sents mainly the mechanical changes in the body under considera- 
 tion, we can, by suitable combination, similarly interpret any 
 other reversible change of state represented in this pv diagram. 
 
 Isothermal Change 
 
 However, because of its general importance and because of 
 its bearing on the temperature-entropy diagram, we will here also 
 tell, in the same physical terms, what happens when our ideal 
 gas undergoes isothermal change with increase of volume. As 
 the temperature in the final state is equal to that in the initial 
 one, the quantity [^ 2 ]=fc 2 does not change and therefore C does 
 
 not change nor (see Eq. (5), p. 50) does the number -j- of mole- 
 cules possessing the velocity change. The variety of velocities 
 
 Cr 
 
 in the final state is therefore the same as in the initial state and 
 does not at all contribute to that necessary increase in the num- 
 ber of complexions (configurations) for which we are looking. 
 
 The direction of the velocity of a molecule would be another 
 variety element, but as the final volume evidently possesses as 
 many velocity directions as the initial volume, this element or 
 co-ordinate will not contribute to increased complexity in the 
 final state. But, as the volume has increased, the final state 
 will contain more unit volumes (and these can be taken as small 
 
AND OF THE SECOND LAW 71 
 
 as we please) than the initial state. As it is here equally likely 
 that a particular molecule will be found in any one of these unit 
 volumes, it is evident that the increase of volume will add increased 
 variety to the location or configuration of the molecules and by 
 indulging in the swapping of places inherent in the production of 
 complexions, we see that said increment of volume will make 
 the number of complexions in the final state greater than in the 
 initial state, which in turn means that the entropy in the final 
 state is also greater. This accords with experience, but it can 
 also be seen from the formula 
 
 Entropy S=constant+Npogf 7+log F], . . (31) 
 
 derived by PLANCK (p. 63 of Vorl. ii. Theor. Physik), from 
 probability considerations, for the state of thermal equilibrium. 
 Here k is the universal constant (see p. 66) and the other terms 
 have the same meaning as before. 
 
 Isentropic Change 
 
 The last reversible process, to be here physically interpreted, 
 is isentropic change from the initial state of thermal equilibrium 
 to its final state. Evidently only the physical elements under- 
 lying the bracketed term in Eq. (31) need to be considered. 
 
 As we are considering isentropic change (dS=o), it does not 
 make any difference whether on the one hand we think of this 
 isentropic change as accompanied by an increase in temperature 
 and decrease in volume, or on the other hand think of said change 
 as taking place with decrease of temperature and increase of 
 volume. Suppose we assume the latter kind of change. Then 
 from what has preceded we know that increase of volume by 
 itself would increase the number of complexions of the final 
 state, also, from what has gone before, we know that the drop 
 in temperature by itself will lead to decrease in the number of 
 complexions in the final state. These two influences acting 
 
72 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 simultaneously therefore tend to neutralize each other and if 
 they exist in the proper ratio, derivable from the bracketed quantity 
 in Eq. (31), they will completely balance each other and produce 
 no change whatever in the number of complexions while passing 
 from the initial to the final state of equilibrium, i.e., will produce 
 no change whatever m the entropy of the gas under consideration. 
 In isentropic change Nature has no preference for its various 
 states. 
 
 The temperature-entropy diagram considers mainly thermal 
 changes, and as we have considered the influence of both of its 
 co-ordinates in the number of complexions, we can ascertain by 
 proper combination, for any reversible change of state, the corre- 
 sponding character of the change in the number of complexions. 
 It is evident, too, that in the diagram any reversible change of 
 state is equivalent, so far as the change of entropy in the one body 
 is concerned, to an isentropic change combined with an isothermal 
 change, the latter only affecting the result, so far as change in 
 nttmber of complexions is concerned. 
 
 SECTION B 
 OF THE FUNDAMENTALLY IRREVERSIBLE PROCESSES 
 
 If we consider only heat and mechanical phenomena and do 
 not include electrical occurrences, the irreversible processes may 
 be grouped in four classes: 
 
 (a) The body whose changes of state are considered is in 
 contact with one or more bodies whose temperatures differ by a 
 finite amount from its own. There is here flow of heat from 
 hot to cold and the process is an irreversible one. 
 
 (b) When the body experiences friction which develops heat 
 it is not possible to effect completely the opposite operation. 
 
 (c) The third group includes those changes of state in which 
 a body expands without at the same time developing an amount 
 of external energy which is exactly equal to the work of its elastic 
 
AND OF THE SECOND LAW 73 
 
 forces. For example this occurs when the pressure which a 
 body has to overcome is essentially (that is, finitely) less than 
 the body's own internal tension. In such a case it is not possible 
 to bring said body back to its initial state by a completely opposite 
 procedure. Examples of this group are: steam escaping from 
 a high-pressure boiler, compressed air flowing into a vacuum tank 
 and a spring suddenly released from its state of high tension. 
 
 (d) Suppose two gases existing at the same pressure and 
 temperature are on opposite sides of a partition; when the par- 
 tition is quickly removed the two gases will diffuse or mix. These 
 gases will not unmix of themselves and the diffusion process is 
 an irreversible one and is somewhat like the process considered 
 under (c). 
 
 The foregoing facts and propositions have in the main already 
 been stated in this presentation and it will be profitable to make 
 comparisons with the definition of irreversible and reversible 
 events given on p. 30 and with the examples on pp. 31, 32. 
 
 HEAT CONDUCTION 
 
 The group under head (a) represents the irreversible processes 
 which perhaps occur most often, namely, the direct passage of 
 heat, by conduction or radiation, from a hot body to a cold 
 body, here say from a hot gas to a cold gas. The former loses 
 in heat energy what the latter gains. As radiation phenomena 
 have very special features of then* own and for the present may 
 be said to be outside of our selected province, we will confine 
 our attention to heat conduction alone. Moreover, for our present 
 purpose, we will suppose said flow or change to take place without 
 alteration of volume of either the hot or the cold gas. Then will the 
 hot gas experience a drop in temperature and the cold one a rise 
 in temperature. We have already treated such isometric changes 
 and know that the number of complexions is thereby diminished 
 in the originally hotter body and increased in the originally colder 
 
74 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 one. If this increment is greater than the accompanying decre- 
 ment, then the final outcome of this direct passage from hot to 
 cold is an increase in the total number of complexions of the 
 two gases. There will then, by our precise definition, be a con- 
 responding increase in the total entropy of the two systems. It 
 is foreign to our present purpose to prove in an independent, 
 purely mechanical way, that such excess does finally exist and 
 will here content ourselves with the well-known and simple 
 thermodynamic expression for this excess, 
 
 (32) 
 
 where Q is the heat energy thus directly transferred from the 
 hot to the cold body, TI the absolute temperature of the hot body 
 and T 2 that of the cold body. 
 
 THE WORK OF FRICTION is CONVERTED INTO HEAT 
 
 The group under head (&) contains a class of events which 
 usually attends, in one form or another, most natural phenomena. 
 
 We will here consider an interesting (but perhaps too special) 
 case, namely, the experiment performed by W. THOMSON and 
 JOULE on the flow of gas through a porous plug. The plug 
 obstructed the uniform, non-conducting, passage through which 
 the gas was forced without sensibly changing its velocity of flow: 
 (See LORENZ' Technische Warmelehre, p. 275). It can easily be 
 shown (in L., p. 274) that with an ideally perfect gas, 
 
 Final temperature T 1 2=-T'i= initial temperature. 
 
 As a matter of fact, there was an actual though slight drop in 
 temperature found to exist with the most perfect gases available. 
 Evidently the process was a throttling one, reducing the larger 
 initial pressure to the smaller final one, which reduction was of 
 course accompanied by a corresponding increase in volume. 
 
AND OF THE SECOND LAW 75 
 
 Assuming that an ideally perfect gas was employed in the 
 experiment, and that the final state for our consideration is that 
 corresponding to its attainment of thermal equilibrium, we see 
 that because of the unchanged temperature there is here no loss 
 of internal energy, for the work consumed by the friction of the 
 porous plug is all returned to the gas by the heat developed by 
 said friction. Moreover, the + and external work in this 
 experiment also balance. Now although there has been no loss 
 of energy there has been a growth of entropy corresponding to 
 the evident increase in the number of complexions. This increase 
 is exactly equal to that found for reversible isothermal change 
 of state when accompanied by an increase in volume, and the dis- 
 cussion is therefore not repeated here. 
 
 One phase of the above process is the conversion of mechanical 
 work into heat through the medium of friction. 
 
 INCREASE OF VOLUME WITHOUT PERFORMANCE OF EXTERNAL 
 WORK BY ELASTIC FORCES OF THE GAS 
 
 This case of an irreversible process comes into group c. We 
 will consider here JOULE'S well-known experiment with the air 
 tanks, in which the compressed air, initially stored in the one 
 tank, was allowed to discharge into the other tank which, at the 
 start, contained only a vacuum. At the end of the experiment, 
 when thermal equilibrium obtained, the temperature in the two, 
 now connected, tanks was the same as originally existed in the 
 compressed-air tank. Here of course it is assumed that the air 
 exchanged no heat whatever with the outside. 
 
 As the final state, like the initial state, is in thermal equilibrium, 
 and possesses the same temperature, we can ascertain the total 
 change in the number of complexions as we did when discussing 
 isothermal and reversible changes and because of the accompany- 
 ing increase in the volume of the air, find that here as there the 
 number of complexions has increased and that therefore the 
 entropy of the air has increased in this case. 
 
76 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 We might rest satisfied with this conclusion, but additional 
 light will be shed on entropy significance if we consider more 
 in detail the intermediate stages of this evidently irreversible 
 process. The rush of air from the full to the empty tank produces 
 whirls and eddies of a finite character and it is only when these 
 have subsided, by the conversion of the visible or sensible kinetic 
 energy of their particles into heat, that thermal equilibrium 
 obtains. But at each intermediate stage (while still visibly whirl- 
 ing and eddying) the .gas possesses entropy, even while in the 
 turbulent condition. This is clear from our present physical 
 definition of entropy, namely, the logarithm of the number of 
 complexions of the state, for it is evident that even in this turbulent 
 state it possesses a certain number of complexions, however 
 difficult mathematically it may actually be to find this number. 
 BOLTZMANN found an expression for any condition ; PLANCK gave 
 it the form of Eq. (18), p. 63, 
 
 En tropy = 5* = constant -&/ log /-<7, ..." (33) 
 
 where ~k = 1.346 (io~ 16 ) (in theC.G.S. system) is a universal constant, 
 function / is the law of distribution of the particles and their 
 velocity elements and a = dx-dy-dz'd-dr}'dt t is a sort of fictitious 
 elementary region in a six-dimensional space. From its deriva- 
 tion and definition the value given for entropy S in Eq. (33) 
 depends only on the state of the body at the instant in question 
 and does not at all depend on its history preceding this instant. 
 
 The difference between the value of 5 for the final state (say, 
 as given for a gas by Eq. 20) and the value of S as given by Eq. (33) 
 for the instant, constitutes the driving motive which urges the 
 gas toward thermal equilibrium. A similar difference or driving 
 motive is the underlying impelling cause of all natural phenomena. 
 
AND OF THE SECOND LAW 77 
 
 OF THE DIFFUSION OF GASES 
 
 This case of an irreversible process comes under group d. 
 Concerning this phenomenon J. W. GIBBS established the follow- 
 ing proposition: 
 
 " The entropy of a mixture of gases is the sum of the entropies 
 which the individual gases would have, if each at the same temper- 
 ature occupied a volume equal to the total volume of the mixture." 
 
 That the total entropy will be larger as a result of the mixing 
 detailed under d, p. 73, maybe inferred from the following consid- 
 eration: When two gases are thus brought together, it is more 
 probable that in any part of the total space available for this 
 mixture there will be found both kinds of molecules than only 
 one kind of these molecules. 
 
 But this irreversible process can be explained in a more dis- 
 tinctly physical way. The two gases are originally at the same 
 pressure and temperature; they mix without other changes 
 occurring in surrounding bodies; the mixture (when diffusion is 
 completed) is at the same pressure and temperature as the 
 original gaseous constituents. Considering each gas by itself, 
 what has happened as the result of diffusion is that each gas in 
 its final state occupies a larger volume than in its initial, unmixed, 
 state. The presence of the other gas in the mixture in no wise 
 changes this fact. Of course this increment in volume is accom- 
 panied by a corresponding decrement in its pressure, without 
 change in temperature. A sort of isothermal change of state 
 has taken place in the passage from one condition of thermal 
 equilibrium to the other. We have already seen that then the 
 number of complexions of the gas increases and consequently 
 also its entropy. The sum of the increments of the number of 
 complexions separately experienced by the two diffusing gases 
 constitutes an increase in the total number of complexions over 
 and above the total number of complexions existing in both gases 
 
78 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 before diffusion. There is of course a corresponding increase in 
 entropy due to such diffusion. 
 
 All these irreversible processes are passages from less stable 
 to more stable conditions, from less probable to more probable 
 states, or summarizing: 
 
 There is in Nature a constant tendency to equalize tempera- 
 ture differences, to convert work into heat, to increase disgrega- 
 tion and to promote diffusion. 
 
 This tendency has also been described as the tendency in Nature 
 to pass from concentrated to distributed conditions of energy. 
 
 The four irreversible processes just discussed are all sponta- 
 neous ones, i.e., they occur without the help of agencies external 
 to the bodies directly engaged in the transformations. 
 
 It is evident that the foregoing statements are really identical, 
 expressing the same thought in different ways. 
 
 SECTION C 
 
 NEGATIVE CHANGE OF ENTROPY; SOME OF ITS PHYSICAL 
 FEATURES OR NECESSARY ACCOMPANIMENTS 
 
 A negative transformation in any part of a system is the 
 diminution of entropy which it experiences, and this we know 
 means a diminution in the number of complexions of the part 
 considered. But there are some features of such negative trans- 
 formations which, while they do not in themselves constitute any 
 additional principle, deserve special mention. 
 
 Before we make such mention, however, we will anticipate 
 a little, and state the Second Law in forms which will make said 
 features obvious: 
 
 In an irreversible cycle the sum of the changes of entropies 
 experienced by all the bodies concerned is greater than zero. 
 When the cycle is reversible in all of its parts, then said sum 
 of entropy changes is equal to zero. 
 
 A corollary from this theorem is that, in a cycle, 
 
AND OF THE SECOND LAW 79 
 
 All the negative transformations present all the positive 
 transformations that occur. 
 
 f an irreversible 1 
 
 When there is simply \ ., 1 } process without the 
 
 [ a reversible J r 
 
 cyclic feature, then the sum of the entropies of all the bodies par- 
 ticipating in any one occurrence is, at the end of the change of con- 
 
 \ greater than ] 
 
 dition \ j . \ that at the beginning. 
 
 [ equal to J 
 
 From this we see that a negative change of entropy always 
 keeps company with an equal or greater positive change of entropy. 
 
 Again, for sake of simplicity, use a gas as an illustration; 
 then we may say: (i) Every possible negative transformation in a 
 gas is always accompanied by a net positive transformation in 
 the other and necessary external agencies. (2) All possible 
 negative transformations in a gas are reversible ones. We here 
 use the word possible because there is an impossible class of 
 negative transformations, namely, those which, so far as order 
 and directness are concerned, are the very opposites of the so-called 
 spontaneous changes of state. 
 
 It will suffice here to enumerate these opposites: Without 
 external help (a) to pass heat from a cold to a hot body, (b) to 
 decrease the volume of a gas, (c) to convert the heat of friction 
 directly back into the work which called it forth, (d) to separate the 
 gaseous constituents of a mixture. 
 
 By way of contrast we may add, that the so-called spontaneous 
 (irreversible) processes were all positive transformations which 
 took place without any change whatever in surrounding bodies. 
 
80 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 SECTION D 
 
 PHYSICAL SIGNIFICANCE OF THE EQUIVALENTS FOR GROWTH or 
 ENTROPY GIVEN ON PAGES 42-43 
 
 According to equivalent (i) growth of entropy is a passage 
 from more to less available energy. The comment already made 
 on p. 42 indicates sufficiently that this increase in unavailability 
 is due to the growth of the ungovernable features of molecular 
 motions as number of complexions increases. 
 
 Equivalent (2) states growth of entropy to be a passage from 
 a concentrated to a distributed condition of energy. In this 
 scattered state the energy is certainly less controllable and for 
 the same reason as that given concerning equivalent (i). 
 
 Equivalent (3) is based on the idea of irreversibility, and we 
 saw on p. 36 that the growth in the number of complexions is 
 the measure as well as the criterion of irreversibility. This growth 
 is therefore a sufficient and necessary feature of this equivalent. 
 
 The equivalents grouped under (4) are all based on the theory 
 of probabilities. We have seen on pp. 36, 62, and elsewhere, 
 that the probability W of a state is the logarithm of the number 
 of complexions of the state. This number is therefore a necessary 
 feature of this set of equivalents and hence constitutes its 
 physical significance. 
 
 The set of equivalents grouped under (5) are all closely 
 related, their dependence being more or less indicated by the 
 order in which they are there stated. The outcome of the series 
 is that growth of entropy corresponds to an increase in the 
 number of complexions. 
 
 The mathematical concept stated under (6) covers more than 
 molecular configurations; it covers configurations whose elements 
 are those of energy as well, and has been successfully applied by 
 PLANCK in problems dealing with the energy of radiation. Every 
 such configuration has a number of complexions. 
 
AND OF THE SECOND LAW 81 
 
 SECTION E 
 
 PHYSICAL SIGNIFICANCE OF THE MORE SPECIFIC STATEMENTS 
 OF THE SECOND LAW GIVEN ON PAGES 44-47 
 
 In making here the contemplated comparisons and interpreta- 
 tions we must keep in mind the three helpful propositions given 
 on p. 44. 
 
 The conservative statement under (i) is confessedly based 
 on the Calculus of Probabilities as applied to a mechanical system. 
 We repeat here therefore what was said about (4) of the preceding 
 series of equivalents, namely, that the number of complexions 
 of the state is a necessary feature of this statement of the second 
 law and therefore constitutes its physical significance. 
 
 The statement under (2) is a common one. As each of the 
 exact definitions of the entropy for every natural event has been 
 shown to depend solely on the number of complexions of a system 
 (all the bodies participating in the event being considered a part 
 of the system) we have here likewise in this number an adequate 
 physical explanation of the second law. 
 
 Statements (3), (8) and (9) have already been derived and 
 explained in this presentation (see pp. 45, 46) as the result of the 
 growth of the number of complexions in every natural event, 
 when all the bodies participating in the event are considered. 
 
 Statement (4) is only a slight variation of (3) and needs no 
 special comment here. 
 
 The same may be said of the three forms under (5). 
 
 The statement in (6) is only a corollary resulting from the 
 use of (3) or (4) or (5). 
 
 The statement in (7) of the second law may be objected to 
 because the underlying definitions are not entirely free from 
 ambiguity and because it lacks a scientifically general character. 
 But it expresses compactly a matter of great consequence in 
 technical circles. Moreover its explanation in our physical terms 
 
82 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 is very simple and direct, viz., when waste is incurred there is a 
 growth in the number of complexions, the complexity of the 
 molecular motions has been increased. Less of the stored-up 
 energy is available, less is capable of being directed into certain 
 technical channels. Evidently the greater the complexity of 
 the molecular motions the less governable they are by any direct 
 external force or influence we can bring to bear. This is because 
 we are unable to act directly on the individual molecules and 
 sway them to our special technical purpose. Our external forces 
 and agencies can only operate on the aggregates comprising our 
 system and must obey the one-sided law imposed on all such 
 aggregates. 
 
AND OF THE SECOND LAW 83 
 
 PART IV 
 SUMMARY: 
 
 THE CONNECTION BETWEEN PROBABILITY, IRREVERSIBILITY, 
 ENTROPY AND THE SECOND LAW 
 
 SECTION A 
 
 (i) Prerequisites and Conditions Necessary for the Application 
 of the Theory of Probabilities 
 
 THESE may be briefly stated to be (a) atomic theory, (b) the 
 likeness of particles (or elements), (c) very numerous particles, 
 and (d) " elementary chaos." 
 
 The first prerequisite is that the body (here a gas) is made up 
 of small, discrete particles. This atomic theory has long been 
 the foundation stone of chemistry, and is again coming into 
 deserved esteem in Physics pure and simple. (See simple and 
 clear article in Harper's Monthly, June, 19/0). But this minute 
 subdivision must be accompanied by the particles being of the same 
 kind, or at least belonging to comparatively few groups, each con- 
 taining many particles of the same sort. This likeness is necessary; 
 for only from this likeness results law and order in the whole 
 from disorder in the parts. If the constituents were of many 
 different kinds, the results in the aggregate would not be so simple 
 as we actually find them to be. There is an example of this sort 
 of complexity in chemistry. We have already intimated that the 
 particles of each kind must be very numerous, but special emphasis 
 must be laid on this prerequisite. If we ask how numerous these 
 
84 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 elements must be in order that the Theory of Probabilities may 
 be applicable, the answer is, as many constituents as are necessary 
 to determine the mean values which define the state in the macro- 
 scopic sense (i.e., in the aggregate condition). An idea of the 
 extent to which Nature carries this subdivision is furnished by 
 the fact that one grain (avordupois) of air, under standard con- 
 ditions, contains, 
 
 14 (io 20 ) molecules, 
 
 -, 
 i.e., millions of billions of particles! 
 
 The last one of said prerequisites is " elementary chaos/ r 
 and needs further elucidation and limitation; we will therefore 
 go into this feature at greater length. 
 
 BOLTZMANN has used the term " molekular-ungeordnet " 
 (molecularly disordered) to designate this chaotic condition of 
 the particles, and PLANCK has introduced a more general term 
 still, " elementar-ungeordnet " (elementary disorder or chaos) 
 in order to make the method applicable to phenomena like radia- 
 tion, in which the elements are not atoms or particles but partial 
 oscillations of different periods. The essence of the matter seems 
 to consist in excluding from consideration all such regularities 
 in the conditions of the elements as would lead to results at variance 
 with the well-known laws of physical phenomena, justifying this 
 exclusion by the assumption that no such elementary regularities 
 obtain in Nature. This only means that not all of the many 
 molecular arrangements, which are conceivable from the purely 
 mechanical standpoint, are actually realized. For instance, 
 in an isolated gaseous system we could conceive of a succession 
 of elementary states at variance with the principle of conservation 
 of energy; such a set would obviously not be realized. This 
 exclusion or limitation leaves room for various hypotheses as to 
 said elementary disarrangement, but to be admissible they must 
 all permit of the legitimate application of the Theory of Prob- 
 abilities, the best one being ultimately determined by its agreement 
 
AND OF THE SECOND LAW 85 
 
 in the whole with known facts or laws. Evidently by prearrange- 
 ment and precomputation there could be obtained molecular 
 arrangements which would establish long-continued regularities, 
 which would furnish mean results in the aggregate, that would 
 be at variance with the well-known behavior of Nature. All 
 such cases are here excluded. 
 
 According to PLANCK the unregulated, confused and whirring 
 intermingling of very many atoms (in the case of a monatomic 
 gas) is the prerequisite for the validity of this hypothesis of 
 " elementary chaos." 
 
 (2) Differences in the States of "Elementary Chaos" 
 
 When we consider the general state of a gas we need not think 
 of the state of equilibrium, for this is still further characterized 
 by the condition that its entropy is a maximum. 1 
 
 Hence in the general or unsettled state of the gas an unequal 
 distribution of density may prevail, any number of arbitrarily 
 different streams (whirls and eddies) may be present, and we 
 may in particular assume that there has taken place no sort of 
 equalization between the different velocities of the molecules. 
 To conceive of said differences we may assume beforehand, in 
 perfectly arbitrary fashion, the velocities of the molecules as well 
 as their co-ordinates of location. But there must exist (in order 
 that we may know the state in the macroscopic sense), certain 
 mean values of density and velocity, for it is through these very 
 mean values that the state is characterized from the aggregate 
 (macroscopic) standpoint. The differences that do exist in the 
 successive stages of disorder of the unsettled state are mainly 
 due to the molecular collisions that are constantly taking place, 
 thus changing the velocity and locus of each molecule. 
 
 Let us for sake of brevity speak of the state of permanence 
 
 1 The rest of the paragraph is a repetition of what was stated at middle of p. 19. 
 
86 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 finally attained by this chaotic mass as the normal state, and all 
 the preceding chaotic states as abnormal states. 
 
 (3) Number of complexions, or probability, of a chaotic state. 
 
 It was shown, in an earlier portion of this presentation, that 
 each such chaotic state (abnormal or normal) is characterized 
 by its number of complexions, which is determined by the Theory 
 of Probabilities. This number is a variable one for the successive 
 abnormal states and is a fixed and a maximum one (under given 
 external conditions) for the normal state. Now BOLTZMANN 
 (by the application of the Theory of Probabilities to this chaotic 
 state) has shown that the means of these states vary in one direction 
 only, in such a way that the probable number of complexions 
 of the successive abnormal states continually grows till it attains 
 its maximum in the normal and permanent state. 
 
 SECTION B 
 IRREVERSIBILITY 
 
 This one-sidedness of the average action or flux constitutes and 
 sharply defines what is meant by irreversibility. It does not 
 imply that the motion of any particular atom cannot be reversed, 
 but that the order in which these averages (or the number of 
 complexions) occur cannot be reversed. We have here a process, 
 consisting of a number of separately reversible processes, which 
 proves to be irreversible in the aggregate. This is not the only 
 possible characterization of the property of irreversibility inherent 
 in all natural events, but is perhaps as general and exact a one 
 as can be enunciated. Superficially speaking, from the confused 
 and irregular motions contemplated, it is quite evident that this 
 succession of whirls and eddies cannot be worked directly back- 
 ward to bring about, in reverse order, the finite physical state 
 which initiated them; for the effecting of such an opposite change 
 
AND OF THE SECOND LAW 87 
 
 would demand a co-operation and concert of action on the part of 
 the elementary constituents which is felt to be quite impossible. 
 It will not be so general and scientific, but perhaps more easily 
 apprehended, if we put this result in terms of human effort, 
 namely, " by asserting that any process is irreversible we assert 
 that by no means within our present or future power can we 
 reverse it, i.e., we cannot control the individual molecules." 
 
 SECTION C 
 ENTROPY 
 
 We have seen above that the inevitable growth in the number 
 of complexions is the mark of irreversibility; the number of 
 complexions at any stage can also in a certain sense be regarded 
 as the measure, index or determinant of that stage or state of the 
 system of elements under consideration. Any function of the 
 number of complexions can be regarded as such measure, index 
 or determinant. Now it has been shown by BOLTZMANN that 
 the expression found thermodynamically for the quantity called 
 entropy differs only by a physically insignificant constant from 
 the logarithm of said number of complexions. But the latter 
 may properly be regarded as a true measure of the probability 
 of the system being in the state considered. BOLTZMANN has 
 defined the entropy of a physical system as the logarithm of the 
 probability of the mechanical condition of the system and PLANCK 
 has cast it into the numerical form, 
 
 S=!i.35 log e ("probability")io- 16 -f constant K 
 = 1.35 log e (number of complexions) io- 16 + const. K; 
 
 where S is the entropy of any natural state of the body and K is 
 an arbitrary constant, the numerical value of the first term of the 
 second member is the quotient of the energy (expressed in ergs) 
 
88 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 divided by the temperature (in centigrade degrees). In English 
 units and the F.P.S. system this numerical value is 5.50 (io~ 24 ). 
 From the whole development we see that entropy S depends 
 only on the number of complexions; it should not be considered, 
 as is sometimes done, as of the same dimensions of energy or 
 anything that may generally be called a factor of energy. 
 
 SECTION D 
 THE SECOND LAW 
 
 It is evident that all these results have for their original basis 
 the Theory of Probabilities. Consequently, because these con- 
 clusions are thus based, they must be interpreted according to the 
 general method underlying this Theory. This method essentially 
 is the determination of average (mean) values and calling them 
 the probable ones. We therefore conclude that each state is 
 characterized by the mean number of complexions belonging 
 to that state, that is, by this mean number which changes always 
 in a one-sided way, ever in the same sense, inasmuch as it inevitably 
 and invariably grows till the normal, settled condition is reached. 
 
 For the sake of clarity we must keep in mind that the motions 
 of the individual atoms are reversible and that in this sense the 
 irreversible processes are reduced to reversible ones. But the 
 process as a whole is not reversible because, by the very act of 
 complete reversal, we would suspend the general, chaotic character 
 of the elementary motions and give them to this extent a special, 
 prearranged feature which would be more or less hostile to the 
 original definition of " elementary chaos." The irreversibility 
 is not in the elementary events themselves, but solely in their 
 irregular arrangement. It is this which guarantees the one-sided 
 change of the mean value characteristic of each one of the successive 
 states of the process. 
 
 Now remembering that the kernel of the Second Law is that 
 all processes in Nature are irreversible, or, that all changes in 
 
. AND OF THE SECOND LAW 89 
 
 Nature vary in one direction only, we can, in the light of what of 
 has just preceded, repeat the following precise, scientific state- 
 ment: 
 
 " The Second Law, in its objective-physical form (freed from 
 all anthropomorphism) refers to certain mean values which are 
 found from a great number of like and ' chaotic ' elements." 
 
 If we now go back to what constitutes the kernel of the Second 
 Law, we will see the relevance and force of PLANCK'S enunciation 
 of this law: 
 
 "It is not possible to construct a periodically functioning 
 motor which effects nothing more than the lifting of a load and 
 the cooling of a heat reservoir." 
 
 The proof of this is purely experimental and cumulative, and 
 the same may be said of the earlier statement of this law, " all 
 changes in Nature vary in one direction only." The character 
 of this proof is, moreover, exactly like that for the First Law, 
 the Conservation of Energy, and has the same sort of validity. 
 
 When we compared and interpreted the current statements of 
 the Second Law (pp. 44-47) we enunciated and made use of 
 three helpful propositions that will now be repeated : 
 
 (a) All cases of irreversibility stand or fall together; if any one 
 can be reversed all can be reversed. 
 
 (b) Any general consequence of any one correct statement of 
 the Second Law may be regarded as itself a valid and com- 
 plete statement of the Second Law. 
 
 (c) The summary of all the necessary prerequisites (or con- 
 ditions) for determining Entropy may be regarded as a 
 complete and valid statement of the Second Law. 
 
 In this connection it will also be helpful to remember PLANCK'S 
 statement: " In order that a process may be truly reversible it 
 will not suffice to declare that the mediating body is directly 
 reversible, but that at the end, everywhere in the whole of Nature, 
 the same state must be restored which existed at the beginning 
 of said reversible process." 
 
90 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 As regards the use of helpful proposition (a) : 
 
 We know that PLANCK'S motor statement of the Second Law 
 was grounded on the well-known irreversible passage of heat from 
 a cold to a hot body. But to show the mutual interdependence (a) 
 of one irreversible change on every other, we will instance in illus- 
 tration the case of a frictional event, or the conversion of mechan- 
 ical work into heat. 
 
 If this frictional occurrence could by any simple or complex 
 apparatus be made completely reversible so that everywhere, in 
 the whole of Nature, the same state would be restored which 
 existed at the beginning of the frictional occurrence, then such 
 an apparatus would be the motor contemplated in PLANCK'S 
 statement of the Second Law, for this periodically running 
 apparatus would convert heat into work without any other change 
 remaining. A similar line of argument, with a similar result, 
 could be pursued with every other case of irreversibility that could 
 be adduced. It is evident that, with the help of the above-given 
 propositions (a), (6), and (c), the Second Law can be cast into 
 many other valid forms. 
 
 We close this presentation of the meaning of the Second Law 
 by the remark that this law has no independent significance, for 
 its roots go down deep into the Theory of Probabilities. It is 
 therefore conceivable that it is applicable to some purely human 
 and animate events as well as to inanimate, natural events; 
 provided, of course, that the former possess numerous like and 
 uncontrolled constituents which may be properly characterized 
 as " elementar-ungeordnet," in other words, provided the variable 
 elements present constitute adequate haphazard for the Calculus 
 of Probabilities. 
 
AND OF THE SECOND LAW 91 
 
 PART V 
 REACH AND SCOPE OF SECOND LAW 
 
 SECTION A 
 
 ITS EXTENSION TO ALL BODIES 
 
 CLAUSIUS extended the operation of the Second Law or, what 
 is the same thing, the scope of entropy, to alj. bodies. See RUHL- 
 MANN'S " Handbuch d. mech. Warmtheorie," Vol. I, pp. 395-405. 
 
 BOLTZMANN says in this connection: " As regards entropy, 
 solid and liquid bodies do not differ qualitatively from perfect 
 gases; the discussion of the entropy of. the former, however, 
 presents greater mathematical difficulties." 
 
 Certain features of the entropy of solid and liquid bodies 
 have, however, been derived with the help of ideal gases as tem- 
 porary auxiliaries. We consider this argument the simplest and 
 therefore now give an outline of PLANCK'S presentation of the 
 matter. 1 
 
 PLANCK'S PROOF THAT ALSO FOR ANY OTHER BODIES THAN GASES 
 THERE REALLY EXISTS A FUNCTION WHICH POSSESSES THE CHAR- 
 ACTERISTICS OF ENTROPY; THE MAIN STEPS ARE NUMBERED 
 
 (i) Expression of entropy for an ideal gas and properties of 
 entropy. 
 
 (2) (a) S-M(C.logr+logv+const); . . (34) 
 
 d'Q 
 
 (35) 
 
 Thermodynamik, 2d Ed., pp. 87-100. 
 
92 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 where the elastic forces do a work = />dF; strictly speaking, d'Q is 
 not differential of Q the heat supply. 
 
 (3) Two gases (i) and (2) thermally connected, are maintained 
 at same temperature but different pressure and change adiabat- 
 ically while experiencing change of volumes; then it can be shown 
 that for this finite change, 5i+5 2 = constant, that is for the two 
 gases the sum of the final entropies = Si l +S2 1= Si +$2 = sum 
 of their initial entropies. No other change is effected in any 
 other bodies but in these two gases; here emphasis is laid on 
 preposition in; for the work done may be the lifting or lowering 
 of a load and such change of location in rigid bodies involves 
 no change of inner energy. Changes of density in external bodies 
 can be also avoided by having the two gas tanks located hi a 
 vacuum. 
 
 (4) A similar proposition can be established for a system of any 
 number of gases by successively treating the gases in pairs as above. 
 The theorem then reads: "If the gas system as a whole possesses 
 the same entropy in two different states then the system can be 
 brought from one state to the other in a reversible manner without 
 changes .remaining in other bodies." 
 
 (5) We know that the expansion of an ideal gas without doing 
 external work and receiving any heat supply is an irreversible 
 process. The consequence is that the entropy of this gas increases. 
 It follows at once that " it is impossible to diminish the entsopy 
 of an Meal gas without changes remaining in other bodies." 
 
 (6) The same result obtains for a system of any number of 
 ideal gases. Consequently "there exists in the whole of Nature 
 no means (be they of the mechanical, thermal, chemical or electrical 
 sort) of diminishing the entropy of a system of ideal gases, without 
 changes remaining in other bodies." 
 
 (7) "If a system of ideal gases has changed to another state (pos- 
 sibly in an entirely unknown way) without changes remaining 
 in other bodies, then the final entropy can certainly not be smaller, 
 it can only be greater than or equal to the initial condition. In 
 
AND OF THE SECOND LAW 93 
 
 the former case this process is an irreversible one, in the latter 
 case a reversible one. 
 
 " Equality of entropy in the two states therefore constitutes 
 a sufficient and at the same time a necessary condition for the 
 complete reversibility of the passage from one state to the other, 
 provided no changes are to remain behind in other bodies." 
 
 (8) "This proposition has a very considerable range of validity; 
 for there was expressly no limiting assumption made concerning 
 the way in which the gas system reached its final condition; the 
 proposition is therefore valid not only for slowly and simply 
 changing processes but also for any physical and chemical proc- 
 esses provided at the end no changes remained in any body out- 
 side of the gas system. Nor need we believe that entropy of a 
 gas has significance only for states of equilibrium, provided we can 
 suppose the gas mass (moving in any way) to consist of sufficiently 
 small parts each so homogeneous that it possesses entropy." l 
 
 Then the summation must extend over all these gas parts. 
 " The velocity has no influence on the entropy, just as little as the 
 height of the heavy gas parts above a particular horizontal plane." 
 
 (9) "The laws thus far deduced for ideal gases can in the 
 same way be transferred to any other bodies, the main difference 
 in general being that the expression for the entropy of any body 
 cannot be written in finite magnitudes because the equation of 
 condition is not generally known. But it can always be shown 
 and this is the decisive point that for any other body there 
 really exists a function possessing the characteristic properties 
 of entropy." 
 
 Now let us assume any physically " homogeneous body, by 
 which is meant that the smallest visible space parts of the system 
 are completely alike. Here it does not matter whether or no 
 the substance is chemically homogeneous, i.e., whether it consists 
 
 1 If the motion of the gas is so turbulent that temperature and density cannot 
 be defined, then we must have recourse to BOLTZMANN'S broader definition of 
 entropy. 
 
94 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 of entirely like molecules, and consequently it also does not here 
 matter whether in the course of the prospective changes of state 
 it experiences chemical transformation. . . . When the substance 
 is stationary the whole energy of the system will consist of the 
 so-called ' inner ' energy Z7, which depends only on the mass and 
 inner constitution of the substance, which constitution is conditioned 
 by the temperature and density." 
 
 (10) Let us suppose that with such a homogeneous body there 
 is conducted a certain reversible or irreversible cycle process which 
 therefore brings the body exactly back again to its initial con- 
 dition. Let the external influences on the body consist in the 
 performance of work and in heat supply or withdrawal, which 
 heat exchange is to be effected by any number of suitable heat 
 reservoirs. At the end of the process no changes remain in the 
 body itself, only the heat reservoirs have altered their state. Now 
 let us suppose the heat carriers in the reservoirs to be composed 
 of purely ideal gases, which may be kept at constant volume or 
 under constant pressure, at any rate only be subject to reversible 
 changes of volume. According to the last proved proposition, the 
 sum of the entropies of all the gases cannot have become smaller, 
 for at the end of the process no changes remain in any other body, 
 not even in the body which completed the cycle process. 
 
 (n) "Letd'Q be the heat gained by the body from some reser- 
 voir in an element of time and T the temperature of the reser- 
 voir 1 at the same moment, then the change of entropy experienced 
 by the reservoir at this instant will be 
 
 and in the whole course of time all the reservoirs together will 
 experience the entropy change 
 
 1 It does not here matter what the temperature of the body is at this instant. 
 
AND OF THE SECOND LAW 95 
 
 and then we know that there must be satisfied the condition 
 
 _ S > or S < , ____ (36) 
 
 which is the form in which CLAUSIUS first enunciated the Second 
 Law. 
 
 (12) Another condition for the process considered is furnished 
 by the First Law. For each element of time d'Q+A = dU, where 
 U is the inner energy of the body and A the work expended upon 
 it in an element of time by external means. 
 
 Now let us consider a more special case in which the external 
 pressure at each instant is equal to the pressure p of the suppos- 
 edly stationary body. Then the external work will be represented 
 
 by 
 
 ....... (37) 
 
 and then it follows that 
 
 . ..... (38) 
 
 (13) Furthermore let the temperature of each heat reservoir, 
 at the instant when it comes into use, be equal to the simultaneous 
 temperature of the body; then the cycle process becomes a revers- 
 ible one and the inequality of the second law becomes an equality, 
 
 (39) 
 
 and substitution of above value for d'Q gives 
 
 ^dU + pdV 
 
 -- =o ....... (40) 
 
 In this equation there occur only quantities referring to the 
 state of the body itself and therefore it can be interpreted without 
 
96 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 any reference to the heat reservoirs. It contains the following 
 proposition : 
 
 " If a homogeneous body by suitable treatment is allowed to 
 pass through a series of continuous states of equilibrium and 
 thus finally to come back to its initial condition, the summation 
 of the differential, 
 
 dU+pdV 
 
 for all the changes of state will be equal to zero. From this follows 
 at once that if the change of state is not allowed to continue to 
 the restoration of the initial condition (i), but is stopped at any 
 state (2), the value of the sum 
 
 '*dU+pdV 
 
 TJ (41) 
 
 will depend solely on the final state (2) and on the initial state 
 (i), and not on the course of the passage from i to 2." l 
 
 " The last expression is called by CLAUSIUS the entropy of 
 the body in state 2, referred to state i as the zero state. The 
 entropy of a body in a particular state is, therefore, like energy, 
 completely determined down to an additive constant depending 
 on the choice of the zero state." 
 
 (14) " Let us again designate the entropy by S, then 
 
 ^dU + pdV 
 
 o 
 
 1 This is evident from the fact that the quantities U, p, V, and T, under the 
 integral are each a function of the state only and do not depend on its past history. 
 This falls far short of being true for turbulent states, for which it is difficult to 
 get p and T. PLANCK does not make the preceding statement, but gives instead 
 a rigorous proof based on cyclical considerations. 
 
AND OF THE SECOND LAW 97 
 
 or, what amounts to the same thing, by 
 
 , dU+pdV 
 
 (42) 
 
 which reduced to the unit of mass becomes 
 
 du + pdv 
 
 (43) 
 
 " This is evidently identical with the value found for an ideal 
 gas. But it is equally applicable to every body when its energy 
 U = Mu and volume V=Mv are known as functions, say, of p 
 and T, for the expression for entropy can then be directly deter- 
 mined by integration. But since these functions are not com- 
 pletely known for any other substance we must in general rest 
 content with the differential equation. For the present proof, 
 however, and for many applications of the Second Law it suffices 
 to know that this differential equation really contains a unique 
 definition of entropy." 
 
 As with an ideal gas, we can now always speak of the entropy 
 of any substance as a certain finite magnitude determined by 
 the values of the temperature and volume at the instant, and 
 can so speak even when the substance experiences any reversible 
 or irreversible change. Moreover, the differential equation (43) 
 is applicable to any change of state, even an irreversible one. 
 
 In thus applying the idea of entropy there is no conflict with 
 its derivation. The entropy of a state is measured by a reversible 
 process which conducts the body from its present state to the 
 zero state, but this ideal process has nothing to do with the changes 
 of state that the body has experienced or is going to experience." 
 
 " On the other hand, we must emphasize that differential 
 equation (43) for ds is valid only for changes of temperature and 
 volume and is not so for changes of mass or of chemical composi- 
 
98 THE PHYSICAL SIGNIFICANCE OF ENTROPY 
 
 tion. For changes of the latter sort were never considered in 
 denning entropy." 
 
 (15) " Finally, we may designate the sum of the entropies of 
 several bodies as the entropy of the system of all the bodies, 
 provided the system can be subdivided into infinitesimal elements 
 for which uniform density and temperature can be assumed; 
 but velocity and force of gravitation do not at all enter into the 
 expression for entropy." 
 
 SECTION B 
 GENERAL CONCLUSION AS TO ENTROPY CHANGES 
 
 Now that the existence and value of entropy have been estab- 
 lished for every state of any body, we can proceed to draw general 
 conclusions in much the same way as that followed with the ideal 
 gases. The general result is : 
 
 "IT IS IN NO WAY POSSIBLE TO DIMINISH THE ENTROPY OF A 
 SYSTEM OF BODIES WITHOUT HAVING CHANGES REMAIN IN OTHER 
 BODIES." 
 
 If we admit to the system all the bodies participating in the 
 process, this theorem becomes: 
 
 " Every physical and chemical process occurring in Nature 
 takes place in such a way that there is an increase in the sum of 
 the entropies of the bodies in any way participating in the process" 
 
 We will close with BOLTZMANN'S statement: 
 
 " The driving motive (or impelling cause) in all natural events 
 is the difference between the existing entropy and its maximum 
 value" 
 
D. VAN NOSTRAND COMPANY 
 
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