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PREFACE T O T H E FIRST EDITION
The publication of yet another text on the well-explored topic of thermodynamics requires some commentary: such a venture may be justified on the grounds that as scientists our perceptions of any subject matter continually change; even as traditional and established an area as chemical thermodynamics is not exempt from such a subtle transmutation. Thus, there appears to be merit in a continuing series of expositions of the discipline of thermodynanics that differ perceptibly from linear combinations of discussions found in prior texts and monographs. In the present volume there occur several departures from conventional treatments, among them: (i) the presentation of the Second Law based on a simplified approach to Carath(~odory's method; (ii) a reasonably comprehensive treatment of thermodynamics of systems subjected to externally applied fields~ special emphasis has been placed on the systematics of electromagnetic fields and on gas adsorption processes, concerning which there has been much confusion; (iii) detailed investigations on the uniqueness of predictions of properties of solutions, in the face of a bewildering array of standard states, of methods for specifying composition, and of equilibrium constants; (iv) a rationalization scheme for the interpretation of phase diagrams; (v) a discussion of the thermodynamics of irreversible processes, centered on the macroscopic equations. Most of the above topics are not covered in detail in existing texts. Throughout, emphasis has been placed on the logical structure of the theory and on the need to correlate every analysis with experimental operating conditions and constraints. This is coupled with an attempt to remove the mystery that seems so often to surround the basic concepts in thermodynamics.
xi
oo
Xll
PREFACE TO THE FIRST EDITION
Repeatedly, the attention of the reader is directed to the tremendous power inherent in the systematic development of the subject matter. Only the classical aspects of the problem are taken up; no attempt has been made to introduce the statistical approach, since the subject matter of classical thermodynamics is selfconsistent and complete, and rests on an independent basis. The course of study is aimed at graduate students who have had prior exposure to the subject matter at a more elementary level. The author has had reasonable success in the presentation of these topics in a two-semester graduate class at Purdue University; in fact, the present book is an outgrowth of lecture notes for this course. No worked numerical examples have been provided, for there exist many excellent books in which different sets of problems have been worked out in detail. However, many problems are included as exercises at various levels of difficulty, which the student can use to become facile in numerical work. The author's indebtedness to other sources should be readily apparent. He profited greatly from fundamental insights offered in two slim volumes: Classical Thermodynamics by H. A. Buchdahl and Methods of Thermodynamics by H. Reiss. Also, he found instructive the perusal of sources, texts, and monographs on classical thermodynamics authored by C. J. Adkins, I. V. Bazarov, H. B. Callen, S. Glasstone, E. A. Guggenheim, G. N. Hatsopoulos and J. H. Keenan, W. Kauzmann, J. Kestin, R. Kubo, P. T. Landsberg, F. H. MacDougall, A. MOnster, A. B. Pippard, I. Prigogine, P. A. Rock, and M. W. Zemansky. Specific sources that have been consulted are acknowledged in appropriate sections in the text. He is greatly indebted to Professor L. L. Van Zandt for assistance in formulating the thermodynamic characterization of electromagnetic fields. Most of all, he has enormously profited from the penetrating insight, unrelenting criticism, and incisive comments of his personal friend and colleague Professor J. W. Richardson. Obviously, the remaining errors are the author's responsibility, concerning which any correspondence from readers would be appreciated. It is a pleasant duty to acknowledge the efforts of several secretaries, Jane Biddle, Cheryl Zachman, Nancy Holder, Susan Baker, and especially Konie Young and Barbara Rosenberg--all of whom cheerfully cooperated in transforming illegible sets of paper scraps into a rough draft. Special thanks go to Hali Myers, who undertook the Herculean task of typing the final version; without her persistence the manuscript could not have been readied for publication. Dr. Madhuri Pai contributed greatly by assisting with the proofreading of the final manuscript. In a matter of personal experience, it is appropriate to acknowledge several meaningful discussions with my father, the late Richard M. Honig, who was an expert in jurisprudence and who readily saw the parallels between scientific methodology and the codification of law. He persisted with questions concerning the nature of thermodynamics that I could not readily answer and was thereby indirectly responsible for the tenor of the present volume. Last, it is important to thank my immediate family, particularly my beloved wife, Trudy, for much patient understanding and for many sacrifices, without which the work could have been neither undertaken nor completed.
j. M. Honig
July 1981
PREFACE T O T H E S E C O N D EDITION
The present volume is an upgraded version of a reference text published by Elsevier under the same title in 1982. The goals of the presentation have remained unaltered: to provide a self-contained exposition of the main areas of thermodynamics and to demonstrate how from a few fundamental concepts one obtains a whole cornucopia of results through the consistent application of logic and mathematical operations. The book retains the same format. However, Section 1.16 has been completely rewritten, and several new sections have been added to clarify concepts or to add further insights. Principal among these are the full use of thermodynamic information for characterizing the Joule-Thomson effect, a reformulation of the basic principles underlying the operation of electrochemical cells, and a brief derivation of the Onsager reciprocity conditions. Several short sections containing sample calculations have also been inserted at locations deemed to be particularly instructive in illustrating the application of basic principles to actual problems. A special effort has also been made to eliminate the typographical errors of the earlier edition. The author would appreciate comments from readers that pertain to remaining errors or to obscure presentations. It remains to thank those whose diligence and hard work have made it possible to bring this work to fruition: Ms. Virginia Burbrink, who undertook much of the enormous task of converting the typography of the earlier edition to the present word processor format; Ms. Gail Shively, who completed this onerous task and patiently dealt with all of the unexpected formatting problems; and Ms. Sophia Onayo, who compiled the index and the table of contents.
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PREFACE TO THE SECOND EDITION
Purdue University has provided a very comfortable milieu in which both the writing and the later revision of the book were undertaken. It is a pleasure to express my appreciation to various individuals at Academic Press who encouraged me to prepare the revised text and who were most cooperative in getting the book to press. Last, this task could not have been completed without the support of my beloved wife, Josephine Vamos Honig, who gave me much moral support after the death of my first wife, as well as during the book revision process, and to whom I shall remain ever grateful.
j. M. Honig Purdue University
Chapter i
FUNDAMENTALS
I. 0
INTRODUCTORY COMMENTS
In this chapter the fundamental concepts of thermodynamics are introduced in the form of the four basic laws.
The procedure
is
with
reasonably
concept heat
axiomatic,
of temperature
flow;
(ii)
the
so
that
without
definition
one
can deal
initially having of
energy
as
a
(i)
the
to refer
to
function
of
state,
after a general introduction to the concept of forces;
(ill)
the
derivation
Carath~odory's performance
of
Theorem,
the
entropy
rather
than
characteristics
functions
of
state
emphasis
is
placed
mathematical homogeneous
are on
properties. functions
of heat
then
by
use
of
generalization
of
engines.
introduced
systematically Lastly,
is
function
the
introduced,
by
A variety
and
considerable
exploiting
important and
used
of
their
concept
of
to provide
framework for analyzing the properties of open systems.
a
We end
with a discussion of stability problems. The reader should examine not only the individual steps in the derivation, presentation, relation
i. I
also
the
internal
structure
the exploitation of Maxwell's equations,
between
experimental
but
commonly
information,
used
thermodynamic
of every and the
functions,
and
such as equations of state.
INTRODUCTORY DEFINITIONS
To understand the concepts of thermodynamics we must agree on the meaning of some basic terms discussed below:
2
I. FUNDAMENTALS
(a) System" A region of the universe set apart from the remainder of the cosmos for special study. (b)
Surroundings"
Regions
immediately
outside
of
and
contiguous to the system under study. (c) Boundaries"
Partitions that separate the system from
its surroundings. Commentary"
It is of the utmost importance to delineate
a system adequately surroundings. paradoxical actual
and to distinguish
Failure results.
physical
to do The
this
boundaries
constraints
such
it properly
leads as
from
its
to nonsensical
and
may
represent
walls,
or
either
conceptual
designs such as geometric surfaces. (d)
Body"
The
total
physical
contents
of
a
specified
region of the universe. Commentary"
In order
to be able
to describe
physical
properties of the body or to carry out measurements that do not disturb
the characteristics
of the body,
its volume
must be
large compared to the atomic scale, typically at least 10 -15 cm 3 in s ize. (e) Homogeneous and Heterogeneous system is uniform throughout
System" A homogeneous
in all its physical properties.
A heterogeneous system comprises several different homogeneous parts in close proximity. (f) Subsystem"
A portion
of a system,
singled out
for
special study. (g) Continuous System" One whose physical properties vary continuously as a function of position within the system. (h) Open (Closed) Systems"
Systems in which an exchange
of matter with its surroundings is (is not) allowed to occur. (i) Permeable Boundaries" Boundaries that enclose an open system. (j)
Semipermeable
Boundaries"
Boundaries
that
permit
passage of certain chemical species, but that are impenetrable to others. (k)
Diathermic
Boundaries"
Boundaries
impermeable
to
matter flow but which permit other changes to occur inside the enclosed system through heating or cooling of the surroundings.
INTRODUCTORY DEFINITIONS
3
(I) Adiabatic Boundaries and Systems" Boundaries that are impervious
to matter flow and that render the enclosed system
totally unresponsive to processes in which the surroundings are heated or cooled. (m) Isolated System" One that is surrounded by boundaries which
render
the enclosed system totally unresponsive
to any
changes in the surroundings. Commentary"
For
a
distinction
between
adiabatically
isolated and completely isolated systems, see Exercise One
should
also
note
external
manipulations
magnetic,
radiation,
perturbations
systems
of
applied
or
be
perturbed
fields
gravitational
through
(e.g. ,
electric,
fields).
These
excepting the
Boundaries of a system may be physical,
or,
imaginary ones.
(n) Thermodynamic are selected
may
can be achieved in all situations
isolated system. in some cases,
that
i.i.7.
Properties"
for a description
Physical attributes
that
of a system on a macroscopic
scale. (o)
Thermodynamic
Equilibrium"
A
state
of
the
system
where, as a necessary condition, none of its properties changes measurably over a period of time exceedingly long compared to any possible observations on the system. Commentary" checked
out,
through
external
properties.
as If
In each a
instance
sufficiency
manipulations the
response
the
system needs
condition, to is
all out
by
sorts of
to be
subjecting of
changes
proportion
to
it in such
applied deformations and the system cannot be returned to its earlier
state on lifting the deformations,
been at equilibrium"
it could not have
If the system is restored to its initial
state on completion of the checking process, without incurring any other changes in the universe, the system is at equilibrium with respect to the tests that have been conducted. In practice
it may be
difficult
to decide
equilibrium state has been achieved or not,
system is subject to very sluggish processes. sufficient response
whether
especially
In particular,
time must be allowed for a system to complete to
external
perturbations.
the
if the
Generally,
it
its is
4
I. FUNDAMENTALS
acceptable to ignore processes which are so slow as to produce no significant changes over time periods that are long compared to
the
observation
ignore
the
laboratory
effect
For
example,
cosmological
to
the
interval
rule
where
of
one
changes
A reasonable
time of any process:
compared
system,
of
experiments.
the relaxation large
interval.
the
may
usually
on
everyday
of thumb
involves
the latter
is very
measurements
on
the
one may regard a state of equilibrium or steady state
to have prevailed during the experimentation. As an example of problems arising in connection with the sufficiency condition,
consider the case of a mixture of H 2 and
02 in a balloon at room temperature.
The fact that there is no
important change in the content of the balloon over many hours does
not
establish
introduction disturbance
that
equilibrium
of platinum black as a catalyst of
the
system
in
this
manner
irreversible change in its properties. H2,
02,
and
prevails,
H20
are
formed
in
shows:
leads
to
small
excursions
of
appropriate
the
system
the
A small a
large,
On the other hand, once amounts,
introduced by heating and cooling are reversible only
as
from
its
changes
and lead to newly
formed
state. (p) matter
Reservoir:
with
the
A
source
system
or
or
for
sink
used
altering
suitable manipulations
to be discussed later.
always
of
assumed
to be
characteristics
remain
such
large
size
essentially
for
the
exchanging
properties
by
A reservoir
is
that
unaffected
its
physical
during
any
exchange process. (q)
Coordinates,
Variables
(of
State),
Degrees
of
Freedom: All three refer to quantities needed to characterize the state of a system at any instant. Commentary:
Ordinarily
independent
set of variables
For
at equilibrium
with
systems a
minimum
number
of
one
selects
for the above
this
linearly
characterization.
characterization
coordinates
a
whose
is achieved values
are
independent of the history by which the equilibrium state was reached. As examples one may cite variables such as temperature or pressure whose alteration will change the state of a system.
INTRODUCTORY DEFINITIONS
(r)
Intensive
(Extensive)
Variables"
Variables
whose
value is independent of (depends on) the size and the quantity of matter within the region which is being scrutinized. (s)
Thermodynamic
interrelation
between
Function several
of
State"
variables
describes a property of the system.
A
of
mathematical state,
which
The suitable manipulation
of such functions provides useful information to the observer of a system. Commentary"
Generally,
such functions
are useful
only
where a system is at or very close to equilibrium, because only in these circumstances can a simple functional interrelation be anticipated. (t) State Space, Configuration Space, or Phase Space" An abstract
space constructed as an aid in the visualization
processes.
Each variable
is assigned
an axis
on which
point represents a numerical value of the variable. space
is then formed by a mutually orthogonal
of any
A (hyper-)
disposition
of
these axes about a common origin. (u) Representative reflects
Point" Any point in phase space that
the physical properties
of the system for which
the
phase space was constructed. (v) Macroscopic
Process"
Any change
in the system that
leads to an alteration of its large-scale properties. (w) system
in
Path"
The
succession
its
passage
from
a
of
states
specific
traversed
initial
by
state
the to
a
specific final state. (x) succession
Quasistatic
Process"
of equilibrium
states,
One
path,
altered
consists
of
each of which differs
infinitesimally from its predecessor. irretrievably
that
a
only
The surroundings may be
in such a transition,
and
in a return
the universe may end up in a final state which differs
from the initial state. (y) Reversible
Process"
One whose
path may be
exactly
reversed by a succession of infinitesimal changes in operating conditions;
the original
state of a system undergoing
such a
process may be restored without incurring any other alterations in the universe.
I. F U N D A M E N T A L S
(z) Irreversible Process: One that occurs spontaneously, generally
while
equilibrium. undergone
the The
system
exhibits
original
an irreversible
state
change
severe of
departures
the
system
from
that
has
can be restored only at the
expense of other permanent changes in the universe. Commentary: system
could
Not
in
all
conceivable
principle
be
processes
subjected
to which
can
realized; we shall encounter such cases later.
actually
a be
Operationally,
the distinction between reversible and irreversible processes introduces
an element of patience.
time between successive alterations changes.
Only
a long
steps that involve just infinitesimal
in the system can one hope Clearly,
if one waits
all
dissipative
to produce
effects
such
reversible as
friction
must be avoided also. The
distinction
between
quasistatic
processes may be illustrated by an example.
and
reversible
In a paramagnetic
material a slow increase and subsequent decrease of the applied magnetic field leads to a gradual magnetization and subsequent gradual
restoration
ferromagnetic field
of the initial unmagnetlzed
medium,
the
to a demagnetized
magnetization
of
the
gradual
application
specimen will
system,
but
on
lead
state. of
In a
a magnetic
to a progressive
gradual
removal
of
the
applied field, hysteresis effects cause the system to go, in a succession of quaslstatic in which
a degree
absence
of
the
states,
to a different
of magnetization field.
necessarily quasistatic,
Thus,
is preserved a
reversible
final state, even
in the
process
is
but the converse may not hold.
(aa) Steady State Process: Processes which induce no net alterations
in the state
of a system but which
do alter
the
state of the surroundings. Commentary:
Steady
state
conditions
are distinguished
from equilibrium by the occurrence of processes in which inputs and outputs for the systems remain in balance, alterations occur within the system. do cause alterations
However,
in the surroundings.
so that no net those processes
For example,
in the
passage of a constant electric current through a wire, which is the system,
the number of electrons in any section of the wire
INTRODUCTORY DEFINITIONS
"I
remains constant because of the requirement of conservation of charge.
The
ultimately
rise
be
surroundings. process.
in temperature
balanced The
wire
However,
off is
due
to Joule
by
increased
then
involved
the battery
heating
heat
flow
in
steady
that produces
a
will
to
the
state
the current and
the surroundings to the wire undergo irreversible changes. (bb) Fictitious Processes: These are changes that can be forced
on
a
system
in
a
thought
experiment
but
cannot
be
performed in actuality. Commentary: visualization
Such
and
processes
didactic
are
purposes;
useful
an
early
aids
for
example
is
provided in Section 1.5. The
preceding
understanding.
discussion
points
It is presumed
intuitive
grasp
such as volume V or pressure P. to
explained
the
transfer
through
they are utilized. supply
better
processes,
the
concept of
the various
of
the
variables, relating
of
that
up
energy laws
a matter
tacit
reader possesses
mass must of
of
and
of
mechanical
By contrast, be
very
an
items
carefully
thermodynamics
before
We shall also be able at a later point to
definitions
for
adiabatic
and
diathermic
and for steady-state conditions.
EXERCISES i.i.I Is it appropriate to classify a definition as being correct or incorrect? Conventional or unconventional? Complete or incomplete? Consistent or inconsistent? 1.1.2 If a definition is labeled as differing from the accepted norm, does that make the definition incorrect? 1.1.3 Are there any conceivable circumstances under which a proffered definition should be rejected? Explain. 1.1.4 A solid is connected to a battery by wires and a current is allowed to flow. Must the battery be considered as part of the system? Explain. 1.1.5 An electrical heater is embedded in a solid, and connecting wires are attached to a II0 volt line. Is the heater necessarily part of the system which includes the solid? Explain. i.I.6 Provide several examples which illustrate the distinction between quasistatic and reversible processes.
8
I. FUNDAMENTALS
i. i. 7 Distinguish clearly between boundaries which enclose an adiabatic and those which enclose an isolated system. For this purpose, enumerate several changes in surroundings which can alter the properties of an adiabatically enclosed system.
1.2
TEMPERATURE AND THE ZEROTH LAW OF THERMODYNAMICS
The Zeroth Law of Thermodynamics emphasizes
the
transitive
is based on a statement which
property
that
two
bodies
in
equilibrium with a third are in equilibrium with each other. Here we
restrict
ourselves
to the case where
the mechanical
variables, namely pressure P and volume V, suffice to describe a system at equilibrium:
however,
this approach can easily be
enclosed
by
generalized. Consider explained matter
a
system
in Sec.
but
do
manipulations
i.I,
permit of
these
enclosures
changes
the
diathermic
in
As
exchange
of
the
system
by
example
of
prevent
state
surroundings.
walls.
of
An
this
situation is provided by a Bunsen burner that is placed below a flask containing ice, water and vapor;
the diathermic
glass
walls of the beaker permit the ice to melt in response to the application
of a
flame
steam) and boundary
exterior
to
the
system
(ice,
water,
(flask).
Let two different systems be brought in contact with each other
through
system
I be
diathermic
walls.
characterized
In a field-free
by pressure
region
P1 and volume
Vl,
let and
system 2 by pressure
P2 and volume V 2. Surround the composite
system
an
i
+
equilibrium. four
2
by
isolating
It is then the experience
quantities
P1,
VI,
P2,
arbitrarily and independently. variables
at
adjustable others.
boundary
but
specific is
V2
no
establish
of mankind longer
that
be
the
varied
Rather, having set three of the
values,
determined
can
and
by
the
fourth
the
chosen
is
no
values
longer for
the
This constraint may be manifested mathematically as a
functional relation among the variables:
~3(P1, VI, P2, V 2 ) - O,
(1.2.1)
TEMPERATURE OFTHE ZEROTH LAW OFTHERMODYNAMICS
where ~3 expresses appearing
the interrelation among the four variables
in the argument.
In principle,
Eq.
(1.2.1) may be
solved for any one of the quantities in terms of the remaining three. We now repeat the discussion for the distinct systems i and 3 which are to be combined into a composite and allowed to equilibrate:
at equilibrium
another
functional
interrelation
holds, namely
~2(P1, Vl, P3, V 3 ) Likewise,
O.
combining
equilibrium,
(1.2.2) systems
2
and
3
into
a
composite
at
we obtain
~l(P2, V2, P3, V3) - O.
(1.2.3)
The Ze~oth Law of ThermodynamiGs
asserts
that
if
two bodies are in equilibrium with a third they are in equilibrium with each other. As a result of the Zeroth Law, Eqs. imply Eq.
(1.2.3).
More generally,
(1.2.1) and (1.2.2)
the applicability
of any
two of these relations implies the validity of the third. As with
any other
law in science,
the above
statement
cannot be accepted or rejected by a priori arguments.
It is,
instead, necessary to examine the physical consequences of the statement
and to ascertain whether
are compatible with the law. Inasmuch remained Therefore,
as
equilibrium
unaltered we rewrite
in
the
all physical
This we proceed to do below. has
prevailed,
union
with
dependent
system
systems
i
3
has
or
2.
(1.2.2) and (1.2.3) as
P3-@I(P2, V2, V3)- @2(PI, Vl, V3), in which we have
observations
(1.2.4)
'solved e for P3, w h i c h thereby becomes
variable.
From
function termed ~, namely
(1.2.4)
we
obtain by
the
difference
a
J0
I. FUNDAMENTALS
~I(P2, V2, V3) " ~2(PI, VI, V a ) "
Comparing ( 1 . 2 . 5 )
A(PI, VI, P2, V2, V a ) -
O.
(1.2.5) and invoking the Zeroth
with ( 1 . 2 . 1 )
Law one notes a glaring inconsistency,
in that there appears to
be a functional dependence of A on V 3 which is absent from the function ~s. system
Clearly,
3 when
isolation.
it makes no sense
considering
the property
to have of
to refer
systems
i +
to
2 in
To preserve consistency we must demand that V 3 occur
in ~i and ~2 in such
a manner
(1.2.5) is constructed.
that
it cancels
out when
Eq.
This goal may be achieved in the most
general form by writlng
#i-
(1.2.6)
~I(P2, V2, V3) - f 2 ( P 2 , V2) h(V3) + q(V3)
# 2 " ~2(PI, VI, Va) - f 1 ( P 1 , where
f,
h,
variables;
and
note
both equations.
q that
are
general
the
(1.2.7)
Vl) h(V3) + q(Va), functions
functions
Substitution
of
the
h and q are
in (1.2.4)
indicated
identical
thus yields
f1(P1, Vl) - f2(P2, V2). Similarly,
f1(P1, V I ) -
Eqs.
(1.2.6)
specific
(1.2.8)
consistent with the Zeroth Law,
(1.2.9)
f3(P3, V3).
Observe
that as a result of the restriction and
(1.2.7),
variables
observation. and
V
for
Equations any
us
to regard
functions
is now made for
each
only
system
to
in the
under
they also force the recognition that mutually
at
equilibrium
cannot
be
Moreover, Eq. (1.2.8) and (1.2.9) permit
f1(P1, VI) as a reference
f2, f3 or, by induction,
are to be compared.
inherent
(i. 2.8) or (I. 2.9) may thus be used to
systems
independently varied.
reference
appropriate
characterize equilibrium; P
in
f•
standard
to which
for systems
the
2, 3, or i
TEMPERATURE OFTHE ZEROTH LAW OF THERMODYNAMICS
The
experimental
~
realization
procedure
consists
in
establishing diathermic contact between system i and systems 2, 3,...,
i,...
in succession.
If the value
of the function
does not change in this comparison process,
fl
then by the Zeroth
Law, systems 2, 3, ..., i, ... are all in equilibrium with each other and with I. if any
of
the
standard.
The same conclusion would have been reached
other
systems
had been
chosen
as
a reference
Clearly, the functional interrelation between Pi and
V i in fi(Pi, Vl) for a given system is of great significance. It fi(Pi,
is
Vi)
therefore by
temperature
the
convenient
compact
(function);
to
designate
I"i,
symbol
termed
the
functions
the
empirical
the reason for this choice of name is
clarified in the next section.
Equilibrium between two or more
systems is thus characterized by equality of all fi(Pi, Vl), all
such
i.e. , by equality of the empirical
systems.
equilibrium
then
More their
explicitly" empirical
the pertinent
temperature
If two
systems
temperature
for
are
functions
at are
equal. The function state.
Note
determining
~i - fi(Pi, Vl) is known as an equation
that
the
latter
provides
T through measurements
function fl is arbitrary,
us
with
of P and V.
a
of
means
However,
of the
in the sense that any single-valued
function which increases or decreases monotonically with I" can be used"
it does not matter what
system
is utilized
specification of the empirical temperature. looseness ...
are
in general
variables
(PI, VI),
I, 2,
(P2, Vz),
functions ....
of I".
new function ~[fi(Pi, Vl) ] which
of
their
However,
systems at equilibrium the corresponding the same numerical value
For the
... the various quantities
different
the
One can turn this
into an advantage in the following manner"
different systems i -
for
fl, fz,
independent
for two distinct
functions must yield
We may therefore is to have
introduce
a
such a functional
dependence for different fl that ~i - ~(Pi, Vl) thereby becomes a universal function. terms
of
variables been used;
mechanical
While we have couched our discussion in variables,
any
other
set
of
conjugate
for characterizing a system could have equally well this is discussed more fully below.
I '2
I. FUNDAMENTALS
In the next section we briefly discuss practical ways of establishing temperature scales. EXERCISE
1.2.1 Discuss ways in which the temperature of an adiabatically insulated system may be changed by manipulation of equipment set up in the surroundings. (See also Exercise 1.1.7).
i. 3
TEMPERATURES,
TEMPERATURE SCALES, AND TEMPERATURE
MEASUREMENTS The use of the word ~temperature' state T(P, V)
is clearly meant
in describing the equation of to establish a link between
a
physical property of any system and human sensory perceptions of what Serrln I has termed 'hotness levels'.
These correspond
to our primitive notions of bodies being ~hot' or 'cold'.
The
very fact that two bodies not in equilibrium are generally at different
temperatures
reflects
ordering of hotness levels; properties
systems,
this
quantification
through
the
scales
need
to
establish
some
to be useful in characterizing the
of
temperature
the
I- which
ordering
must
be
establishment should
functions of increasing hotness
be
levels.
capable
of
of
empirical
monotonic
increasing
Thermodynamic
theory
is related to human experience that whenever both pressure and volume increase in a system subjected to changes in its thermal state,
this
corresponds
level of the system.
to
a perceived
rise
in the
hotness
For this reason the equation of state is
well suited to function as an indicator of the hotness under
investigation.
However,
observations
of
level
physical
properties other than functions of state are equally useful: In a
generalization
physical
variables
of
earlier
which
concepts,
change
these
perceptibly
encompass as
a
system
any is
Ij. B. Serrin, Lectures at NSF-CBMS Regional Conference on Mathematical Foundations of Thermodynamics, July 1978, Ball State University.
TEMPERATURES: SCALESAND MEASUREMENTS
advanced such
to
different
as pressure
however, use
|
hotness
Mechanical convenient
quantities; such as the
resistivity,
thermoelectric
are very
variables
there are myriads of other possibilities,
of
and volume
levels.
viscosity,
voltage,
susceptibility,
etc.,
spectral
sound
each
emissivity,
velocity,
of which
responds
in a different
way to alterations in thermal states of the body. experimental
measurement
involves
a
correspondence between hotness levels, property
selected
empirical
for monitoring
temperature
state, T(P, V).
magnetic Each type of
distinct
one- to- one
the particular physical
the hotness
level,
and
the
function I" specified by the equation of
We can thereby correlate the measure values of
the chosen physical variables with the values obtained from -
t-(P, V).
The
arbitrariness
function allows us enormous and
procedures
for
in
the
latitude
temperature
empirical
temperature
in the choice of systems
measurements.
Here
we
must
ultimately be guided by experience and theory to pick from all of the possible
temperature
functions
those few) of greatest convenience be appropriate that
serves
that particular
and utility.
as a reference
standard
of hotness
which other physical variables can be calibrated.
(or
It will also
to single out from available materials
well
one
one set against
This we now
proceed to do. For simplicity one searches for a material
in which the
system provides a natural linear scale for hotness levels. has been known for three centuries
It
that certain gases such as
He, Ar, H2, and the like closely approximate to the relation PV (Boyle's Law) when these gases are kept at a given
-constant
empirical
temperature well
liquified.
In
view
of
above
the
the range where
flexibility
empirical temperature functions
in
they can be
construction
of
(as explained in Section 1.2),
let us adopt the product PV as a direct measure of ~" ~(P, V) - PV.
This
is the
simplest possible
procedure;
as shown
in
Section 1.17 this approach is actually firmly grounded in the basic laws of thermodynamics. temperatures henceforth
serves
shall
as
call
an a gas
Thus, He gas at all but lowest
excellent
test
thermometer,
system,
which
for monitoring
we the
|4
I. FUNDAMENTALS
values Once
of
I" of
the
any
system
mechanical
temperature
is e a s i l y
the v o l u m e
conjugate note
that
only
so
of
the
subsequent
as
gas
the
relation
this
of
PV-
is
is a s s u m e d
which
the
r - 0 when
w i t h water,
ice
interval V100, and
in I" is termed V
represent
V - V0
-
or
centigrade
pressure
the
system
at
I" -
O,
low value),
x i00
to set up
scale,
for
is e q u i l i b r a t e d is in e q u i l i b r i u m
Celsius of
(when the p r e s s u r e
the
is p a r t i c u l a r l y
volume
respectively
at some arbitrary,
a
in
one w h i c h
the
with
low;
of one atmosphere.
degree
equilibrium
satisfied
to be the case.
9 - I00 w h e n w a t e r
the
should
can be a s s i g n e d
Celsius
w i t h steam u n d e r a total p r e s s u r e
is
the
values
at a t m o s p h e r i c
and for w h i c h
let
one
it is n e c e s s a r y
are in use:
so-called
to
I". Also,
sufficiently
measurements,
such scales is
empirical
and
constant
some k i n d of a scale on w h i c h n u m e r i c a l
convenient
equilibrium.
the
constant
as a m e a s u r e
pressure
discussion
Many
in
measured
thermometer
serve
For q u a n t i t a t i v e
to I".
is
specified.
empirical
long
are
it
it is s i m p l e s t to h o l d e i t h e r the p r e s s u r e
the
variable
which
variables
Experimentally or
with
The unit
(~ gas ~
If n o w Vo, thermometer
-
I00,
of the gas t h e r m o m e t e r
and
in I",
is f i x e d
then ~ is m e a s u r e d by
(P fixed),
(1.3.1)
V1o o - V o
or analogously,
if the v o l u m e
is h e l d fixed
(and all p r e s s u r e s
are low),
P - P0
-
P1oo-
where
P0,
x I00
(V fixed),
P100, and
respectively.
P
These
correspond
to
I" - O ,
are to be d e r i v e d
The above m a y be r e w r i t t e n
P
~ -
in E x e r c i s e
I00,
and
r,
1.3.1.
as a d i f f e r e n c e
P0
-
x i00 P1oo"
(1.3.2)
Po
Po
-
x I00 P1oo"
Po
(V fixed),
(1.3.3a)
TEMPERATURES: SCALESAND MEASUREMENTS
I
- T - To,
wherein
(1.3.3b)
we have
T - IOOP/(PI00
" P0);
a new set of t e m p e r a t u r e s
To - lOOP0/(P100
T O is a constant;
in w h i c h shift
defined
T o in zero.
(1.3.3c)
" P0),
the r and T scales
Experiment
has
shown
differ
that
only by a
the q u a n t i t y
To -
iOOP0/(P100 " P0) for the gas t h e r m o m e t e r has the v a l u e of 273.15 degrees
Kelvin
define
the
(now
generally
absolute
called
temperature
kelvlns,
scale
by
T
K). -
Thus, ~
+
we
273.15
(ke ivins ) . It
will
Kelvin
scale
merely
the
turn has
out
a
later
much
that
more
convenience
the
introduction
deep-seated
of
of
significance
establishing
the
the than
direct
proportionality
T-
IOOP/(PIoo
in place clear
of
the
linear
relation
Using establish
Eqs.
one
(1.3.4)
or
calibration
it is e a s i e s t
T1
that
coexistence later, and
It
should
also
be
only
ice,
one
water,
gaseous
fields
the
Celsius
principles
of t h e r m o d y n a m i c s
K and P1 - 4.579 mm Hg.
are
T 1 and
water
with
K,
is n e c e s s a r y
T 1 for
the
which
and vapor.
Conformity
(P/P1)273.16
it
gas
fixed
to select
characterizes as will
then
there
pressure coexist
scale
and w i t h
P1 at in later
to
or T/T 1 ffi
For,
can
only
thermometer.
It turns out v e r y c o n v e n i e n t
temperature
and
point
temperature
if all external
liquid,
(1.3.5)
to set T/T 1 - P/P1 at fixed v o l u m e
single
of
(1.3.5)
(P cons tant).
- V0)
V/V 1 at fixed pressure. for
(1.3.2).
(I. 3.4)
that alternatively,
T - lOOV/(V~00
Here
(V constant)
- Po)
be
the shown
exists
which
one
solid,
equilibrium. fundamental
is a t t a i n e d by s e t t i n g T I ffi 273.16
Accordingly,
for a gas thermometer,
T - (V/V1)273.16 where
K or T -
V 1 and P1 are
the
16
i. FUNDAMENTALS
volume
and
pressure
of
the
gas
established both a temperature
at
273.16
K.
We
have
scale and a means of measuring
the temperature. Gas thermometers tend to be awkward in use. practice,
therefore,
is
to
employ,
where
The general
possible,
other
thermometers that exhibit a near-linear variation of some other property x, with the empirical for this purpose
is the mercury
expands in volume as ~ rises. i
-
temperature
~. A common device
or alcohol
thermometer which
For many liquids the quantity
(I/V)(aV/aT)e remains approximately constant.
(aV/aT)p
Thus
aV, which shows a direct proportionality between AV and AT -
A~,
to the extent to which ~ is truly constant and V is very
large (and nearly constant)
compared to AV. In thermometers of
this type one measures AV as a change in length of the liquid column maintained in a capillary attached to a large reservoir of liquid. Many other temperature sensors are in use. convenient
and
reproducible
resistance
thermometer.
is
Here
a bifilar, the
One which is
annealed
resistance
platinum
R and
absolute
temperature T are related by the expression R - R0(l + aT + bT 2 +
cT 3) ,
where
established
by
R0
a,
b,
c,
are
calibration.
constants
Quite
commonly
thermocouples are used as thermometers; -
which
must
be
two-junction
these produce an emf E
aiAr + a2A~ z + a3A~ 3, where Ar is the difference
in empirical
temperature between the two junctions,
one of which is held at
a
semiconductors,
standard
temperature.
Crystalline
carbon
resistors, paramagnetic salts, and optical pyrometers are also in common use in their appropriate temperature ranges indicated in Fig.
1.3.1.
A detailed discussion of various experimental
techniques that have been used to measure temperatures would go too
far
afield;
the
reader
is
advised
to
consult
the
very
extensive literature on the subject for further details. For convenience
in calibration of thermometers
in their
appropriate ranges, several secondary fixed temperature points have been agreed upon. hydrogen,
Among these are:
the triple point of
the boiling point of hydrogen,
the boiling point of
neon, the triple point of
oxygen, the boiling point of oxygen,
TEMPERATURES: SCALES A N D M E A S U R E M E N T S
| 7
Expansion of l i q u i d s Magnetic su sc ept i bi l i t y
--~~Thermocoup[es
Semiconductors
~ C a r b o n
resistance
~ Ptat~num -~-
~---
~
Gas T(on logarithmic i 0.1
scale)
l lo
i 1
FIGURE 1.3.1.
the
triple
-----1
k 100
N.B.R He 4
Pyrometers~
resistance
N.B.P. N 2
~
1
i
1000
10,000
N.B.P. w a t e r
Useful range of different kinds of thermometers
point
of water,
freezing point of zinc, freezing point of gold. agreed-upon temperatures
the boiling
point
of water,
the freezing point of silver, For details
and for values
the
and the of these
the reader is referred to appropriate
reference books and monographs.
EXERCISES 1.3.1 From the relation 9 - PV derive Eqs. (1.3.1) and (1.3.2). i. 3.2 Look up and then describe the following temperature scales in relation to the Kelvin scale: Celsius, Fahrenheit, Ranklne, and R~aumur. 1.3.3 Look up and then describe the physical principles on which the operation of the following thermometers is based: (a) semiconductors, (b) paramagnetic salts, (c) optical pyrometers, (d) thermocouples. 1.3.4 Describe several feedback systems commonly used to regulate the temperature of a system within a range of + 50 K near room temperature. 1.3.5 Consider the question as to what changes must be made in the approach of the present section if a nonideal gas is to be used as a thermometer.
J8
I. FUNDAMENTALS
1.3.6 What set of physical principles and experimental apparatus is used to measure the temperature of materials between 10 .3 and i K? Of galaxies in outer space? Of the temperature inside the head of a house fly? 1.3.7 The coefficient of linear expansion of Pyrex glass in the range 0-I000 ~ is 3.6 x 10 .8 deg -I, and for mercury V~ V0(r + 0.18182 x 10-31- + 0.0078 x lO-~z). If O~ and IO0~ are taken as fixed points on a mercury-ln-glass thermometer, what does this thermometer read when an ideal gas thermometer reads 40 ~C? 1.3.8 Let a benzene temperature scale (~ be defined by T0~ at the freezing point (5.56~ of benzene, and T IOO~ at its normal boiling point (80.15~ Set up a formula by which you can convert from ~ to ~ and from ~ to K. I. 3.9 'Derlve' the Perfect Gas Law from the combination of Boyle's Law (1660) PV~(T), where I- is a parameter independent of pressure P and volume V; also 'derlve' Charles' Law (1787) P ~(V)T, where ~ is a parameter independent of pressure P and absolute temperature T. 1.3.10 Provide a concise discussion of the types of substances which are suitable as standards in thermometers that are to operate within + I00 K of room temperature. Why must a common material such as water or mercury be excluded from this listing? -
i. 4 We
MATHEMATICAL APPARATUS need
to
investigate
repeatedly
in
equations.
These
several
subsequent
mathematical
manipulations
of
procedures
used
thermodynamic
results must be thoroughly mastered before
one can proceed with the unified description of thermodynamic principles.
Readers are advised to consult mathematical texts
on calculus and geometry for a more thorough exposition of the subject matter.
(a) The first deals with the transformation of variables. The theorems are illustrated below in three dimensions but may readily be generalized.
Consider a function F(x,y,z) of three
independent variables x, y, z, each of which can be expressed in terms of three alternative independent variables u,v,w that are of greater convenience
in characterizing the system:
MATHEMATICAL APPARATUS
x-
I
x(u,v,w),
y-
y(u,v,w),
The variables x,y,z
z
-
(1.4.1)
z(u,v,w).
(as well as the original variables u,v,w)
are not generally to be identified with position coordinates, but
represent
appropriate
independent
interest.
On substitution we find
F(x,y,z)-
F[x(u,v,w),
variables
y(u,v, w), z ( u , v , w ) ] -
of physical
G(u,v,w)
- F(u,v,w). The change
(1.4.2)
in notation from F(x,y,z)
to G(u,v,w)
emphasize that in passing from x,y,z,
to u,v,w,
to write
functional
symbol
procedure because
may
out the relation as
the
result
the physical
original
in
However,
for u,v,w with function
confusion
but
to
one generally
converts F to a different functional form, G. customary
is meant
it is
the
of x,y,z.
remains
same This
convenient
interpretation of the dependent variable
remains unaltered by coordinate transformations. Now
differentiate
(1.4.2)
with
respect
to
u;
by
the
'chain rule' one obtains
~
--
V,W
~
y,z
~
+
V,W
X,Z
with similar relations for aF/av
dF-
~
dx + y,Z
aN
X,Z
dy +
~
+
V,W
X,y
V,W
(1.4.3)
and aF/aw.
aH
,
dz
Next, write out
(1.4.4)
X,y
as
dF-
Xdx + Ydy + Zdz,
(1.4.5)
where X I (aF/ax)y,z ' etc. Then substitution in (1.4.3) leads to the important result
I. F U N D A M E N T A L S
~O
aH
OH
-X
V,W
aH
+Y
V~,W
with comparable
aN
+ Z
V,W
equations
(1.4.6)
,
V,W
8F/av and 8F/aw. From a purely
for
intuitive viewpoint
it appears as if in the differentiation
F with
u
respect
constant
and
(1.4.6).
to
we
the
'differentiated'
The
reader
to
(1.4.3),
equivalent
held should
'coefficients'
only note
which
dx,
dy,
that
explains
in
of
(1.4.5)
dz
to
obtain
(1.4.6)
is
really
the
origin
of
the
apparent anomaly.
(b) A special case of (a) arises when one sets u -- x and eliminates variables
z,w,
thereby
to two.
reducing
Equation
the
(1.4.3)
number
of
independent
then leads directly
to the
important relation
~
~
v
aN ~
y
(1.4.7)
x
v
which shows how one may pass from a quantity constant
v,
constant
to
the
y.
same
This
partial
result
thermodynamics,
particularly
derivatives
the
in
last
8F/ax evaluated at
derivative
finds
many
evaluated
applications
at in
if the product of the two partial
term
of
Eq.
(1.4.7)
may
be
readily
evaluated.
(c) A special alerts
third
equation us
relation
to the may be
result F(x,y) fact
solved
of
-C,
importance where
is obtained
C is constant.
that x and y are not in principle
from This
independent;
for y = y(x)
the form the
so that we
find
dy -
~
dx; F
(1.4.8)
21
MATHEMATICAL APPARATUS
y is now specified as a function of the second variable and its differential
is known as well.
We may then determine
dF =
dx + y
whence
Na
dy = x
~
dx + y
[ [ dx '~81X-Lax/ F
aM
one finds another result of importance,
=
O,
(1.4.9)
namely
8{~xx) = _ (8F/ax)y , F (8F/Oy)x which
reexpresses
quantity
F
derivatives
any
is h e l d in
(1.4.10)
constant
which
differentiated.
partial
F
This
is
differential in
terms
treated
formulation
is
of as
in which
a ratio the
a given
of
partial
quantity
often
needed
in
to
be
later
sections.
(d) Next,
eliminate x by solving F(x,y) - C as x - x(y).
It should be obvious
that this leads to the result
airy] _ _ (aF/ay)x F (aF/ax)y From a c o m p a r i s o n
(1.4.11)
of (1.4.10)
and
(1.4.11)
we
then obtain
the
Recip. rocal Theorem,
(1.4.12) F
(@y/@X)F
The procedure involving the equation F(x,y,z) = C is more complex;
this
relation
longer independent.
shows
that
the
three variables
are no
That is, x,y,z may be interrelated either
through the symbolic equation x = x(y,z) or through y = y(x,z). Then
the differentials
are likewise
of the two dependent
interrelated:
variables
x or y
~,~-
I. FUNDAMENTALS
dx -
dy +
aN
~
z,F
dy
Na
-
dx
Na
+
z,F
Substitute
dz
(1.4.13a)
dz.
(1.4.13b)
y0F
x,F
from (1.4.13b)
I -
into
(1.4.13a)
and collect
dx z,F
terms"
+
z,F
z,F
dz.
x,F
y,F
(1.4.14)
Because Thus,
of (1.4.12)
the right-hand
the left side of (1.4.14)
side may be readily rearranged as
-z,F
x,F
i,
(1.4.15)
y0F
which is known as the Reciprocity
(e) circumstances where
8y/au
vanishes.
The
procedure
where and
Theorem.
described
the evaluation
8x/au
are
easily
F(x,y) - C and set x ffi x(u,v),
below
of 8y/ax obtained.
y = y(u,v).
is
useful
in
is difficult,
but
We
begin
with
Then, by the chain
rule,
~
-~ v
+ y
which may be rearranged
(ay/au)v,F
(aF/ax)y
( ax/au)v,F
( aF/ay)~
v,F
, x
0
(1.4.16)
v,F
to read
(1.4.17)
MATHEMATICAL APPARATUS
2
On introducing
m
F
(ay/au)v.F (ax/au)v.F
(f)
We
relationships
(1.4.10) one obtains the useful result
9
next in
(1.4.18)
consider
mathematics
one as
of
the
applied
most to
fundamental
thermodynamics,
namely Euler's Theorem of Homogeneous Functions.
This theorem
is motivated by a thought experiment in which one container at constant T and P containing nl moles of species
i in volume V
is adjoined to another container of identical size and content under
the
same
conditions.
On
partition
the combined
system has
the
numbers
all
mole
parameters
of
removal twice
species
have been maintained
i,
of
the
internal
the volume
and twice
while
intensive
the
at constant values.
This
is
but one example of a more general situation in which one looks for a function F(x,y,z,...) which has the property that if all independent variables x,y,z,.., are replaced by ~x, ay, ~z,..., then one requires
that the original function F be replaced by
aF: F(ax,ay,az,...)
(1.4.19)
- aF(x,y,z,...).
A function satisfying the requirement (1.4.19) is said to be
homogeneous
reexpress set ~ -
in ~,
of
degree
this requirement I + ~ and examine
one.
It
is
of
interest
to
in another form.
For this purpose
the special
for which
case
E ~ 0.
According to (1.4.19) we demand F[(I + ~)x,
(I + ~)y,
(I + ~)z,...] - (i + E)F(x,y,z,...). (1.4.20)
We can
apply
Taylor's
theorem to the left-hand side; we also
rewrite the right-hand side as
~-4
I. FUNDAMENTALS
F(x,y,z,...)
+ ~x
'N
+ ~y
- F(x,y,z,...)
+ ~z
+
...
+ ~F(x,y,z,...),
(1.4.21)
where we have terminated the series after expansion in the variable ~ ~ O. Then,
F(x,y,z,...)
Thus,
- x
+ y
a homogeneous
'M ~ + z
function
very stringent requirement
of degree
+
the
first-order
....
one
specified by Eq.
(1.4.22)
must
satisfy
(1.4.22),
the
w h i c h is
known as Eu!er's Theorem. A n alternative
d e r i v a t i o n proceeds as follows:
a function F(xl,x2,...Xr) +
for which we write
... + FrdXr, with F i - (@F/axl).
variables
proportlonally:
dF-
Now change
dx I - xldA, FdA;
ratios
unaltered,
of
the
homogeneous F2x2dA +
various
xi's
remain
of
degree
one
in all
... +
FrxrdA,
from which
all independent
dx 2 - x2dA,
xrdA and impose the constraint d F -
Consider
F1dx I + F2dx 2
...,
this implies
xi's.
Then
Euler's
dx r -
that the
and
that
FdA
- F1xldA
theorem
F
follows
is + at
once.
The results obtained so far are s u m m a r i z e d in Table 1.4.1 below.
(g) In conjunction with the foregoing we b r i e f l y discuss thermodynamic
functions
in the m a t h e m a t i c a l systems time.
one
requires
Moreover,
experimentalist (f)
versus
measurement, from
the
of state.
description
This concept arises b e c a u s e of e q u i l i b r i u m
single-valued
functions
properties
of
independent
of
when the e q u i l i b r i u m state is altered what an cares
about
initial
is the c o n f i g u r a t i o n (i)
state
that
is
of the final subject
to
not the specific path by w h i c h the change of state
i to f was
accomplished.
selection of appropriate
This must be r e f l e c t e d
mathematical
w h e n the transition from i to f is
functions,
in the
F, such that
d e s c r i b e d by a s u m m a t i o n of
25
MATHEMATICAL APPARATUS
,i
Table
i
1.4.1
Summary
of R e s u l t s
Listed
in this
Section
Given dF-
X dx + Y d y + Zdz
x-
x(u,v,w)
y-
y(u,v,w)
z - z(u,v,w)
then (I)
~H
I
~H
X
V,W
(2)
( 3)
~
a[~X]
I
~H
Y
+z Ha V,W
V,W
V,W
~
v
+
~ ~
+ y
x
_ (aF/ax)y
(aF/ay)x
F
-i
(4)
Ma Na ~N ~ ~H
when
F(x,y)
- C
F
(5)
z
0 (< 0) w h e n
(compression).
force.
For c o n s i s t e n c y w i t h later d e v e l o p m e n t s
I. 8. I] we now set # - - M, gz
so that the increment
(rather
than u s i n g
of w o r k a s s o c i a t e d with
the
of mass dM, from infinity to height z is given by
gzdM,--
gzMdn,
(1.6.12)
42
I. FUNDAMENTALS
in which M is the gram-atomlc or gram-molecular mass and dn is the increment another
in mole numbers.
possible
entire
One should contrast this with
formulation,
~rw, -
- M, gdz,
for
which
the
system of constant mass M, is simply displaced upward
through the distance dz. physical
processes;
The two versions
one cannot argue
more fundamental than the other.
describe different
that one
formulation
is
Because we ultimately wish to
consider changes in the internal constitution of the systems it turns
out
to
be
easier
to
thread
Eq.
(1.6.12)
into
the
thermodynamic theory than to start with the expression for ~W'. Thls
is
related
to
the
fact
that
in
(1.6.12)
the
internal
thermodynamic coordinates are changed for the system as a whole as additional mass
is inserted at position z, whereas
expression
only
whole
for ~W'
is changed.
For
the elevation further
z for
discussions
the
in the
system as a
relative
to
this
point the reader is referred to Section 6.2. (f)
The work
in subjecting
a charge
electrostatic potential de is ~W' - - qdr
q to a change
in
Here, the situation
is analogous
to the motion of a body through an infinitesimal
distance
a
in
gravitational
field.
An
increase
de
while
preserving q does not change the deformation coordinates of the system.
An
alternative
formulation
is
possible:
Here
an
element of charge is taken from infinity and placed on a body at electrostatic potential r
We will find this approach much
more useful and will generalize it immediately, for
later
equivalent
applications. to
the
The
formulation
result, ~W-
Eq.
in preparation
(1.6.13)
- Cdq.
below,
Consider
is
a body
maintained at a specified electrostatic potential which has a value r
at the position r where its charge density is p(r).
Now let additional charge dq - d3rdp(r)
contained in a volume
element d3r be brought from infinity to position r. The element of work involved in this process then is - d3rr total work for the entire body now reads ~ W -
and the
- ~vd3rr
where the integration is carried out over the volume V of the body. V-D-
According
to Maxwell's
equation for a material medium,
4~p, where D is the electric displacement vector.
Thus,
THE CONCEPT OF WORK
43
dp = (4ff)-iV.dD, 1.4.2,
line
and by use of the vector
(d), we
may
- - (4if)-I fd3r{V.(OdD)
now write ~ W -
- dD.VO(r)},
theorem
in Table
-fd3r(4~)-1(V-dD)r
where the integration must
be carried out over the total region in which the displacement vector has nonvanishing values.
By Gauss' Theorem,
Table
of the
1.4.2,
the first portion
mathematically the surface
equivalent
small;
above integral
is zero.
the
field.
integral
identity
accordingly,
for ~IW is
- fd2r(n.OdD)_ _ over
the field exists.
The
that the surface
flux
may be taken to be so remote
is vanlshlngly use
an
expression
of the region within which
boundaries
we
to
llne (j) of
the
first portion
In the second portion of the integral
E-
- VO,
where
E
is
the
electrostatic
Then (1.6.13a)
~W = - (I/4x)fd3rE. dD. For
a
more
elementary
specialized
medium
field
and
interacts
system,
is referred
derivation
It is important
electric
derivation
the reader
sophisticated 1.7.
of the
which
the
more
1.6.2.
A more
in the Appendix,
Section
and
fields
so that an integration
much
that E and D are the local
displacements,
with
also
to Exercise
is provided
to recognize
is
that
that
over
are
the
dielectric
external
all space
to
is called
the for.
These two factors render Eq. (I. 6.13a) awkward in manipulation. A formula inherently better suited for later use was derived by Stratton (1941) and Heine increasing
~WHere
(1956)"
the applied electric
The work done on a system by field E 0 in the amount dE 0 is
(1.6.13b)
fvd3rP.dE0 . P
is
the
Operationally, interrelations
polarization
this
quantity
following
must
be
described specified
below. through
of the type P = ~E or P • ~0E0, where ~ is the
electric susceptibility. Appendix;
vector
Equation
(1.6.13b)
a special case is considered should
be
noted"
(i)
is derived in the
in Exercise
Equation
1.6.4.
(1.6.13b)
solely to the work performed on the system of interest;
The
refers P = 0
44
I. F U N D A M E N T A L S
outside
the system.
(1.6.13b)
extends
(ii)
only
that of (1.6.13a)
Correspondingly,
over
the volume
the
integration
of the
is taken over all space.
system,
in
while
(iii) For the total
work involved one must combine Eq. (1.6.13b) with the integral - fd3r(4~)-iE0.d{_0. represents
The
latter
(1.6.13a).
specified
over
all
space,
and
the work involved in energizing space prior to the
insertion of the dielectric. Eq.
extends
by
(iv)
the
P
is
This combination is equivalent to the polarization
interrelation
D-
vector
E + 4~P
which
, (v) E 0 is
is the
applied electrostatic field in vacuo and is to" be held constant on insertion of the system into the field.
(g) which
A similar set of statements applies
a magnetic
placing
the
energized.
field
material
is
applied
in
an
to
a
system,
electromagnet
In one formulation,
to the case in such
which
be ~W' - - •dH; here H is the magnetization. shall,
instead,
involved
provide
in changing
is
then
field to
In this case the
of the system remain unaltered.
a derivation
the
by
one may regard the element of
work associated with the increase dH of the magnetic thermodynamic coordinates
as
field
such
We
for the element of work that
the
thermodynamic
coordinates are altered. The work involved in subjecting matter to magnetic fields H may be determined by considering a local current density J(r) subjected
to a vector potential A(r).
Changes
in the latter
are associated with work according to ~W--
(i/C)fvd3r(J-dA),
(1.6.14)
where c is the velocity of light. VxH-
(4~/c)J which holds
no time variation ~W-
Now use the Maxwell relation
for the special case where there is
in the electric displacement.
- (4~) -I ~d3r{dA.(VxH)}.
By the vector
One obtains
identity line
(g)
of Table 1.4.2 the work increment becomes HI~ = - (4~)-Ifd3r{H. (VxdA + V.(HxdA)}. all regions
The
integration must be carried out over
to which the magnetic
field extends.
portion of the integral can be rewritten by Gauss'
The
second
Theorem so
THE CONCEPT OF WORK
45
that it involves the quantity HxdA which is to be evaluated at
the
fringe
vanishes.
boundaries;
this
part:' of
the
integral
therefore
In the first part we set VxA i B; accordingly,
-- - (I/4~r)fd3rH *dB. In the foregoing, more
elementary
rather
(1.6.15a)
B is the magnetic
derivation
specialized
case,
of
induction vector.
the above
see
Exercise
results, 1.6.3,
Eq.
(1.6.15a)
based
while
elegant derivation is furnished in the Appendix, Again,
For a on
a
a
more
Section 1.7.
is awkward in actual use because H and B
are local fields which reflect
the reaction of the medium
to
the applied field, and because the integration extends over all space.
For practical applications it is more convenient to use
Heine's
(1956) formulation
--
-
(1.6.15b)
~ d3rHo*dM
which is derived in the Appendix, is
considered
in Ex.
1.6.4.
Section 1.7.
Note"
(i)
A special case
Equation
(1.6.15b)
refers solely to the work involved in placing a magnetic medium into
a constant
applied
outside the system. only
over
the
magnetic
induction
(il) Correspondingly,
volume
V
of
the
field
H0;
M-
0
the integral extends
magnetized
material.
(iii)
Equation (1.6.15a) is equivalent to (1.6.15b), augmented by the expression
- ~d3r(4~)-iH0.d~_0, integrated over all space.
(iv)
In the preceding, H 0 is the applied magnetic field vector prior to insertion of the sample;
this quantity is to be held fixed
when the samples are moved into position. moment vector specified by M are magnetic
xH or by M -
susceptibilities;
(v) M is the magnetic x0H0, where X and X0
alternatively,
(vi) Note the difference in sign when comparing
H = B
- 4~M.
(1.6.15b) with
(1.6.13b). (h) When surface effects are important one deals with a geometry Section
where 5.2
is
these devoted
particular to
a
effects
detailed
are
emphasized.
discussion
of
this
46
I.
particular
topic
in the context
of gas adsorption
FUNDAMENTALS
phenomena.
Fig. 1.6.4 shows a setup where in a very thin, elastic film is stretched
across
a wire
frame,
one part of which
is movable.
There is a natural tendency on the part of the film to minimize the
surface
area
Correspondingly,
by
pulling
the
movable
wire
to
the
left.
a force f is required to overcome the surface
force;
the work in moving the wire to the right by dx is ~IW =
- fdx.
The film area A increases by dA = 22dx, where account
must be of the formation of a film on both frame.
Then
~W = -
(f/22)dA;
tension or surface force by ~ -
~W
=-
on
sides of the wire
defining
f/2~
the
!n.terfacial
we obtain
(1.6.16)
-ydA.
(i)
In what
follows
one can always determine
it will henceforth the work performed
be
assumed
that
in any process by
use of the general relation (1.6.1) which involves an integrand formed
as
differential
a
product of
an
of
an
intensive
extensive
variable
variable.
with
Basically,
the this
relation acts as a bootstrap equation by means of which one can specify
the
elements
of
work
which
enter
the
various
thermodynamic quantities of interest that are introduced later. It
is
elements
therefore
of
the
utmost
of work correctly;
importance
failure
to
to do so has
specify
the
in the past
led to problems when dealing with the thermodynamic properties of materials
subjected to externally applied fields.
() G) I I I I i I I I KS k_/
(lh k_J dx
FIGURE 1.6.4 frame.
Setup for expanding a film stretched over a wire
THE CONCEPT OFWORK
47
EXERCISES
1.6.1 (a) In subsection 1.6.1(i) it was stated that the form ~ -fd2 always obtains. Yet Eqs. (1.6.13) or (1.6.15) appear to have two factors such as P and E 0 both of which are intensive variables. Resolve the apparent anomaly. (b) Which is the intensive and which is the extensive variable in each case? 1.6.2 (a) By elementary methods derive the relation -VEdD/4~ for a parallel plate condenser of such size that fringing fields may be neglected; here V is the volume inside the condenser plates, E is the local electrostatic field, D E + 4~P is the electric displacement, and P the electric polarization per unit volume. (b) What feature in this system allows one to confine the derivation to the volume inside the parallel condenser plates? (c) Show that in the absence of any material between the plates ~ J -VEdE/4~-(V/8~)dE z and interpret this result. (d) Prove that the reversible work done in inserting a neutral dielectric material into the condenser is ~ W -VEdP. (e) Explain the significance of the negative sign in these results. 1.6.3 (a) By elementary methods derive the relation ~W - -VHdB/4~ for an infinite solenoid of such size that fringing fields may be neglected; here V is the volume inside the solenoid, H B - 4~M, where H is the magnetic field, B the magnetic induction, and M the magnetic moment per unit volume. (b) What feature in this system makes it possible to restrict the results to the volume inside the solenoid? (c) Show that in the absence of any material inside the solenoid ~ - V H d H / 4 ~ - -(V/8~)dH 2 and interpret this result. (d) Prove that the insertion of an unmagnetized, non-ferromagnetlc material into the previously empty solenoid requires an element of work ~W. (e) Explain the significance of the negative sign in the above relation. 1.6.4 (a) For the elementary case of a very large parallel plate condenser prove that Eq. (1.6.13a) may be rewritten as ~ W VEodDo/8~ + VPdE O. Here E 0 and D o are the electric field and displacement inside the condenser resulting from fixed charges prior to the insertion of a material into the condenser, and E and D are the corresponding quantities after insertion while keeping the fixed charges unaltered. The derivation hinges on the important question as to how D changes in the insertion process while the charges on the condenser remain fixed. (b) Repeat the procedure for the long solenoid, showing that Eq. (1.6.15a) may be rewritten as -VHodBo/81r -VBodM. -
48
I. FUNDAMENTALS
1.6.5 (a) Let the equilibrium state of a simple elastic system be described by three variables: stress a, strain e, and temperature T and choose e as the dependent variable. Introduce Young' s Isothermal Modulus of Elasticity by Y(8o/8e)~ and the coefficient of thermal strain by A (8e/aT)=. Write out the equation of state in differential form for do. (b) State under what conditions e may be considered as a function of state for the system. If de is an exact differential find a differential interrelation between y-Z and A. (c) Using appropriate reciprocity conditions, prove that ( 8 a / a T ) , - Bz, termed the coefficient o~ thermal stress, obeys the relation B z - -AY. (d) Prove that do - Yde + BzdT. (e) Show that o - Y e is a formulation of ~.ooke's Law. 1.6.6 Can one conceive of processes where friction plays a role and for which the forces are conservative? Why or why not? 1.6.7 Calculate the reversible work of compression on I00 g of a liquid when the pressure is increased from I0 to I00 atm at a constant temperature of 20~ The compressibility is - 82 x I0 -B arm -I. Assume that ~ is constant within the pressure range 1 to I00 arm, and that the density of the liquid, p, at 20~ and I atm pressure is 0.792 g/cm 3. What assumptions have you introduced carrying out these particular calculations? 1.6.8 Determine the magnetic field in gauss (oersted) inside a long solenoid containing I0 turns of wire per mm through which a current of 3 amps is passed. I. 6.9 Write down the equation which correlates the applied magnetic field, magnetic induction, and magnetic intensity. Using this relation define the magnetic susceptibility and write an equation expressing magnetic induction solely in terms of the applied magnetic field. On this basis define the permeability and relate it to the susceptibility. 1.6.10 A vertical cylindrical tank of length 77 cm has its top end closed by a tightly fitting frictionless piston of negligible mass. The air inside the cylinder is at an absolute pressure of i atm. The piston is depressed by pouring mercury on it slowly, so that the temperature of the air is maintained constant. What is the length of the air column when mercury starts to spill over the top of the cylinder? 1.6.11 Write down an expression for the potential energy of a magnetic dipole which is at an angle 8 with respect to the applied magnetic field. Recognizing that the magnetic intensity is also the magnetic moment per unit volume, write down an expression for the work required to increase the magnetic intensity infinitesimally.
APPENDIX: WORK IN THE PRESENCEOF ELECTROMAGNETIC FIELDS
4~
1.6.12 Write down an expression for Curie's law pertaining to paramagnetic materials and for the Curie-Weiss law pertaining to ferromagnetic or antiferromagnetic materials. 1.6.13 It was stated in the text that the element of work always involves the product of an intensive variable with a differential of an extensive variable. Yet Eqs. (1.6.13) and (I. 6.16) involve two intensive variables. Explain the apparent discrepancies, and show explicitly how the problem is resolved when the relevant fields are uniform throughout the sample. 1.6.14 Look up in an appropriate text how the differential of the mechanical work term must be modified when a medium with anlsotropic properties is considered; write down the result in appropriate tensorial notation.
1.7
APPENDIX. DERIVATION FOR THE ELEMENT OF WORK IN THE PRESENCE OF ELECTROMAGNETIC FIELDS
We provide an alternative derivation leading to Eqs.
(1.6.13a)
and (1.6.15a) by starting with the Maxwell field equations +
(tic)
aB_lat
Vx~/ - ( 1 / c ) a D / a t In the
above,
-
(l.7.1a)
o
- 4~Jf/c. E,
D,
H,
electric displacement,
(l.7.1b) B,
Jf represent
the
Form
the
field,
magnetic field, magnetic induction,
free current density vectors respectively; light.
electric
scalar
product
of
and
c is the velocity of
(l.7.1a)
with
H
and
of
(l.7.1b) with E and subtract to find
-
-
Next,
-
+
+ (1/c)s
(llc)x.(as/at)
(1.7.2)
(4x/c)E'Jf.
introduce
the
vector
identity
H. (Vxs
-
E- (VxH)
-
( 1.7.3
)
V. (FxH), llne (g), Table 1.4.2. Then
V.(Ex/~) + ( 4 x / c ) E - J t : + ( l / c ) E - ( a D / S t ) +
(1/o) x. (as/a t)
-
O.
~0
I. FUNDAMENTALS
Now integrate over all space. By the vector theorem (j), Table 1.4.2, and with v - ExH, f d a r V . v - fdZr v.n for any vector v, n being the outer surface normal, to
a
surface
boundaries
integral
the first term is transformed
extending
and thus vanishes.
over
infinitely
remote
This leaves
- fd3r E-J~dt - (i/4~)fdar(E.dD + H.dB_).
(1.7.4)
The left-hand side may be rewritten as
J_~.~- pzv~._~- [p~E + c-Zp~!~xs].!~- _f'!~,
(1.7.5)
in which p~ and vf are the density and drift velocity free carriers which constitute
the current J~.
of the
Notice that in
the third relation we introduced the vector identity v~.(vfxB) - 0.
The quantity in square brackets
as formulated by Lorentz.
is the force density f,
It follows that
- fd3rJ~.E dt - - fdZrf.vfdt - ~W, which
is
Section system.
(1.7.6)
clearly
identifiable
as
1.6) when
the electric
field transfers
Equations
Helne's
(1.6.13a),
(1956)
an
increment
+ H.~
+ (V0"~0
reformulation
+ (v-
- E0"~0 + H0"~0 + (E'~0 - S0"~0)
D0)'~0
+ (S0"~0
+ S0"(~
energy
(see
to the
(1.6.15a) now follow directly. of
the
established by taking note of the mathematical
~.~
of work
- H0"~0)
- ~_0) + ( H -
- D'~0) + ~'(~H0)'~.
above
may
be
identity
+ (H0"~
- ~0"~)
~_0) (1.7.7)
In the context used below E0, Do, H0, B 0 are to be regarded as electromagnetic
field vectors that arise from fixed charge and
current distributions existing prior to insertion of the system of interest;
E, D, H, B are the corresponding quantities when
APPENDIX: WORK IN THE PRESENCEOF ELECTROMAGNETIC FIELDS
the body
is present
in the same
5 |
external
charge
and current
distribution. We now the
fields
integrate
penetrate.
Eq.
(1.7.7)
The
third
over all space term
into which
is equivalent
to
(E -
D).d~_0 - - 4zP-E0, because prior to insertion of the body dD 0 dE
in free
volume
of
space; the
4~B0.dM.
integration
system because
system P B 0. -
the
in
may be
the
free
restricted space
to
the
outside
the
The fourth term with B 0 B H 0 reads B0.(dB- - dH)
Again,
the integration may now be restricted to the
volume of the system since in free space M - 0.
The fifth and
sixth terms vanish automatically since in free space B 0 - H 0 and D O - E 0.
When the integration is carried out each of the last
four terms vanishes on account of a vector theorem derived by Stratton 3 (1941).
Thus it follows that
+ fvd3rB0 9d~. The reader
(i. 7.8)
should specifically note
that the integral
on the
left and the first one on the right of (1.7.8) are taken over all space, whereas the remaining integrals on the right extend solely over the volume of the system.
Equation (1.7.8) is thus
very useful in that the first integral on the right represents the work increment associated with changes dD 0 = dD and dB - d ~ in
free
space,
additional
whereas
work
the
increment
remaining arising
integrals
involve
specifically
from
the the
presence of the system.
In general only this latter quantity
is
thermodynamic
of
interest
in
the
analysis
of
systems.
Finally, attention is directed to the difference in signs which occurs in Eq.
(1.7.8) between the third and fourth integrals,
and to the unsymmetric disposition of the quantities
H0, E 0 and
P, M in these same integrals.
.
.
.
.
.
.
.
3J.A.
,
,
,
,
Stratton,
York, 1941), p. 111.
Electromagnetic
Theory
(McGraw-Hill,
New
5 ~,
1.8
I. FUNDAMENTALS
THE FIRST LAW OF T H E R M O D Y N A M I C S
(a) The First Law of T h e r m o d y n a m i c s experience
of
mankind"
adiabatically initial
Let
i,
thermodynamic characterized
xI
{xl}1,
depends
solely on the initial
path
which
is
here
above
from
designated
as E, with
is now p e r f o r m e d
situation
fact
the
that
no
longer
other
adiabatic
The answer
set
of
state
2,
is invariably
found
In
other
words,
involved
Wa
in the
and final values
EI
a.
holds.
This
conditions,
fact
would
seem
of the function E, were it not
changes
process.
initial
also
The
occur
question
which
were
arises
absent
whether
the
in these altered circumstances.
is in the affirmative.
The
First
L.aw of
existence
of
internal
energy
with
any
final depends
a
Thermodynamics
function
of
any
between
state
(2),
solely
characterizing
of
(function)
state
whatsoever,
on
such a concept
later how the quantity
state
system;
E,
for
initial
difference
the
these
guarantees termed
process
AE
the
any
process
state
(i) and
AE
coordinates
states
and
m
E2
xI
-
EI
and
x2
is independent
of
them.
is incomplete E is actually
until
it is e s t a b l i s h e d
to be determined.
The First Law contains an important corollary: an adiabatic
the
which may be c o r r e l a t e d
a given the
the path connecting
processes
it from an
final
under n o n a d i a b a t i c
function E still remains useful
Clearly,
a
and final states
greatly to impair the usefulness the
to
an
In v i e w of Section 1.4 one may specify a f u n c t i o n of
If work
for
on
independent
taken.
and E2, such that AE m E 2 - E I - W
the
following
performed
transforming
Such a change
adiabatic
state,
on the
be
the
OF HEAT
of the type of adiabatic work done and of the
precise
process.
by
m
by x 2 - {xl} 2.
to be independent
Wa
thereby
characterized
variables
is b a s e d
work
isolated system,
state
AND THE CONCEPT
- W a - 0, one can compute
from a m e a s u r e m e n t
or c a l c u l a t i o n of W a.
Since for AE for such
If this same
THE FIRSTLAW AND THE CONCEPT OF HEAT
change
is
now
brought
remains unaltered, Since
AE
- W
53
~
about
via
a nonadiabatlc
but the w o r k performed, 0,
it
is
expedient
to
process,
W, differs introduce
AE
from W a.
a
deficit
function Q such that Q - (AE - W) - 0.
Note
for any of the adiabatic or nonadlabatlc
changes w h i c h connect
the
same
initial
and final
state,
AE
carefully
is a b s o l u t e l y
that
the
same,
but it is the nature of the interaction of the system with its surroundings this
that is altered
sense
different
Q
and
W
may
causative
internal
energy
for the different
be
agents
of
the
considered that
system
as
produce
via
its
processes.
In
measures
of
the
change
in
the
with
the
a
interaction
surroundings. The quantity Q just Basically,
it is seen to be
that attends
Henceforth,
sufficient The
AE
a bookkeeping
we
shall
to
Q
the
type of a d j u s t m e n t
experimental
is incomplete is
to be
until
determined
initial
the process of interest? to locate another and Wa'' to
I
corresponding difference
2,
changes
between
state
i with
in energy, final
and
and
from a knowledge
-
- W.
it has Thus,
are
always
the
be
1.6.
is no adiabatic final
state
path 2 for
initial
of w o r k W a' from state
AEI0
let
W a' + AE21 - W a'' - 0,
W
W a can
Let
equivalently,
quantity
as
experimentally;
adiabatically
E is a function of state,
Historically,
0
In that event it is usually possible
Then, because
calculated
AE;
if there
respectively.
the
Q-
directions
state 0 such that by p e r f o r m a n c e
and
special
For the present
in Section
the system can be brought
states
of
outlined
How may AE be calculated the
for
W a as the m e t h o d par excellence
determination
a s c e r t a i n e d by the methods
that connects
Clearly,
condition
these matters are dealt with in Section 1.19.
the
flow.
adiabatic processes.
of heat
show how
regard
we cling to the relation A E for
the heat
- W a - 0, and Q - 0 for this
to characterize concept
furnished
is called
to the difference b e t w e e n AE and W.
an adiabatic process, case.
introduced
and
AE21 be state
AE20
the
of
0 be
energy
interest.
AEI0 + AE21 + A E 0 2 -
0;
so that AE - AE21 can be
of W a' and Wa''. been
Q ffi AE
the
custom
+ W;
then
to the
deal
with
First
Law
the of
54
I. FUNDAMENTALS
Thermodynamics
finds its analytical expression in the relation
AE - Q - W,
(1.8.1)
which now implies the following"
(a) Q and W are two different
manifestations
transit
separating
of
the
energy
system
in
from
its
surroundings;
changes
in E which
correspond
dynamic
coordinates
of the system,
energies
per
se
in
the
across Q
to alterations but
system.
boundaries and
of
the
they do not
(b)
AE
is
W
incur
thermo-
represent
increased
rendering Q > O, in which case one states conventionally heat flows int0 the system;
that
it follows that Q < 0 represents
flow of heat out of the system and a concomitant the internal energy of the system.
reduction
energy;
it
o__nnthe system,
follows
characterized
that
of
taken
state
state
(their values
in carrying
heat
E-
or work
E I, because
different
processes
defined
by
experimentally
the
energies
can
such
process,
of
the
heat
do
first
depend
their
a
on
the
algebraic
it makes no sense to inquire
state
can
different
Furthermore, law
be
in the
reached
amounts
by
many
of heat
flow
only a difference (or,
there
for
is no
that
such
fixed
in energy
matter,
thing
as
is
'the'
This is reflected in the well-known fact
only be
An interesting W r be
is
Q and W are not usually
system possesses
determined
constant which has no fundamental
and
system
to a reduction
generally
Also,
a given
accessible);
energy of the system. that
that
its internal
b_,y the
out a given process),
involving
and work performance. is
increases
leads
that although
sum is a function of state. how much
in
energy of the system.
It is emphasized
path
which
performed
by W > 0 and that this
the internal
functions
work
a
(c) E is also increased by
rendering W < O, in which case one states conventionally work is performed
by
to within
sidelight
should be brought
flux
work
and
carried out reversibly,
+ AW be the corresponding
an
arbitrary
significance.
associated
out: with
Let Qr a
given
and let Q - Qr + AQ and W - W r
quantities
when the same process
is
THE FIRSTLAW AND THE CONCEPT OF HEAT
55
carried out irreversibly. -
O, so that always A E -
A W -
(b) A comparable differential dE
-
Then, according to the first law, AQ
dQ
Qr - W r -
situation
Q - W.
obtains when we consider
form of (1.8. i), namely
(1.8.2)
dW.
-
the
Here dE is quite properly
the differential
increment
of
the function of state E; given E(xl,... , xl) one finds n
(1.8.3)
dE - ~ (aE/ax~)dx i. i-i By contrast,
the
written
down
in the same manner
changes
in Q or w from
symbol
dQ
and
quantities
dW.
This
can
adiabatic
such
that
as dE we use
both
be
small
these
the
latter
in value on the path one takes however,
according
to
constitutes
an
sum dQ - dW does not.
This
the
concept
is defined
of what to be
system such that at every stage ~ Q this particular
usually
To distinguish
of the system;
now broaden
process.
as dE.
implies
depend
displacement
the algebraic
We
of Q and W cannot
infinitesimals
individually
in a slight (1.8.2),
differentials
any change
O, so that d E -
in the - dW a in
case.
(c) Next, we hark back to the fact that Q and W represent energies
in transit across boundaries.
occurring in
its
that
Thus,
is a paradigm
the
principle
for
It
is
of
surroundings
when
isolated
Conservation
no matter what
solely
an
system
for such a situation.
corollary of the First Law" constant,
any process
totally within a system does not produce
energy.
universe
Therefore,
-
0;
the
It is then seen
Energy
follows
as
a
in isolated systems the energy is
processes
there
of
any change
AE
are
occur
entirely
interactions
within
which
involve
that the energy of a system can be altered.
the energy E for an interactive
system is not fixed;
it.
Thus,
however,
if the system and all of its interactive component surroundings
~6
I. FUNDAMENTALS
are grouped
into an isolated
unit,
continues
to hold for the enlarged
-Q
must
- W,
always
be
then the condition system.
interpreted
The first
to mean
that
AE - 0 law,
AE
changes
in
energy E of the original system are precisely m a t c h e d by energy flows Q and W out of or into heat the
interfacing
boundaries.
and work
Once
reservoirs
more:
energy
across
is
never
generated locally w i t h i n the boundaries of the original system. This concept
is more fully illustrated
in Chapter
At this point we can again provide perspective
on Eq.
A
(1.8.3):
A
Since
E-
a more
6. sophisticated
E(xl,x2,...,Xn)
A
A
we may
A
set _E" - _eiE~ + e2E~ + ... + _enE~ and dx_ - eldx I + egdx 2 +
...
A
+ endxn, with E~ " 8 E / a x i. A
In requiring
A
A
satisfy
el.e j - 0
(1.8.3)
in the shorthand notation:
discussed
(i ~ j)
in Section
1.4(b)
that the unit vectors
A
and el-e • -
i, we
dE-
can
rewrite
Eq.
E" .dx.
The m a c h i n e r y
may now be invoked.
Since E is a
function of state ~E"-dx_ - 0 for any cyclic process;
by Stokes'
theorem,
sufficient
V
x
condition. form
we
E"
-
When
obtain
definitions
0
follows
as
a necessary
this requirement 8E[/axj
-
is w r i t t e n
8E'j/ax i
-
O,
or,
and
out in component on
adopting
for E~, E~, we obtain @ 2 E / a x l a x j - 8 2 E / a x j a x l ,
is a familiar
the
which
result.
(d) The foregoing calls for a more p r o t r a c t e d d i s c u s s i o n of the interchange surroundings. of
state
It is extraordinarily
brought
distinguish
of work and energy b e t w e e n a system and its
about
clearly
surroundings,
and
through
between
the
the
what
execution
performed setting system
up under
performance calculated.
or a
by
the
"work study, of
work
system
to
(lii) can be
be
in the system w h e n w o r k to recognize determined
completely in such
either
them;
the
of work it is not n e c e s s a r y
operating
can
system,
to
to
reservoir," and
(i)
(ii)
on it or by it; and
on
the
link b e t w e e n
be informed about the internal changes is p e r f o r m e d
in all changes of work
constitutes
connecting
note that for the determination
important
that w o r k only
external
to
the
that
the
measured
or
a manner
readily
after
THE FIRSTLAW AND THE CONCEPT OF HEAT
57
The problems which arise are perhaps best illustrated by reference
to
Fig.
insulated enclosure S Mp.
1.8.1,
which
depicts
an
adiabatically
equipped with a movable piston P of mass
The latter rests on release pins r I and r2; the container
is also furnished with stops s I and s 2 which ultimately the
downward
motion
earth's gravitational
of
the
piston
field.
under
the
of
the
Let the space in the enclosure be
totally evacuated and let the release pins the piston now
action
arrest
is accelerated
through
then be retracted;
a vertical
distance
h,
until arrested by the lower stops, s I and s 2.
The volume of the
enclosure is
The work involved
thereby reduced
from V i to Vs
in moving P through the distance h is M~gh (for the problem of sign,
see
Exercise 1.8.5).
~r I
If the system is considered to be
r2
h
-7Sl
S2 [ ~
FIGURE 1.8.1 Schematic diagram depicting a system S, which is an adiabatically insulated enclosure, provided with a movable piston P; r I and r 2 are retractable release pins, and s I and s 2 are stops which arrest the downward motion of the piston under the influence of the earth's gravitational field.
S~
I. FUNDAMENTALS
constituted solely of the space inside the adiabatic enclosure, no work has
been performed
on
the
system
in the process
of
diminishing its volume from V i to V~; however, heat in the form of radiation
crosses
the boundaries
of the system
since
the
surrounding walls are heated through the friction of the moving cylinder and by its sudden arrest. enclosure wall
If, on the other hand,
is included as part of the system,
temperature
indicates
the
then the rise in
that the energy of the system has
been raised by the descent of the piston;
for this adiabatic
system the increase in energy is given by AE - M~gh. Next,
let the container be filled with a gas of pressure
Pi sufficiently low that the released piston compresses the gas to pressure Ps when ultimately arrested by the stops; i.e., the pressure of the gas satisfies the relations Pi -< P -< P~ < M~g/A, A being the cross-section of the piston.
Let the system again
include the adiabatically insulated walls. misconceptions, walls, gas
is still Mpgh, even though there now exists an opposing
pressure
present
P
in the
situation
the
prevailing in vacuum; to
Contrary to popular
the work performed on the system, including the
convection,
stage;
also,
than before, ultimate
range
Pi -< P -< P~.
acceleration
of P
is
However, lower
in
than
the that
at the same time the gas is now subject
turbulence,
and
heating
the walls are heated,
in
the
compression
though to a lesser extent
by the friction of the moving piston and by its
sudden
deceleration.
In
the
absence
of
detailed
information it is impossible to ascertain how much of the work, during
the
descent
of P,
is
converted
into
an
increase
in
energy of the gas, and how much appears as increased energy of the walls.
For nonequilibrium situations this type of analysis
would require the specification of a host of nonthermodynamic variables.
However,
as far as the ultimate equilibrium state
is concerned, none of this matters; after the system (walls and gas), has come to equilibrium,
the increase of energy of the
system is again AE - M~gh, regardless of how AE was originally partitioned between that
the
gas
specification
through without
and walls. of
reference
the
It is clearly
final
state
to the complex
can
fortunate
be
carried
internal changes
of
THE FIRSTLAW AND THE CONCEPT OF HEAT
~9
the system during the process. As the next experiment, let enough gas be admitted to the system
to
support
relation P s -
th e
M~g/A.
piston
Also,
by
virtue
of
for simplicity
the
balancing
consider
where frictional effects may be neglected.
the case
Now, add one grain
of sand at a time to the top of the piston,
thereby forcing P
to move downward slightly at each step against the increasing opposing gas pressure.
Continue this process until the piston
is gently nudged against the lower arrests. the amount - g~~
This time, work in
has been performed, where m(z) represents
the mass of the plston-plus-sand which is present at the height z above the arrests.
A new feature results from this process,
which consists of a series of quasistatic
steps"
The applied
external and resistive internal pressures very nearly balance, and at each stage the gas is only infinitesimally removed from equilibrium.
In
this
circumstance
one
equation of the state of the gas P(T,V) both the work
may
introduce
the
and thereby evaluate
- ~ P(T,V)dV and the energy increase A E -
- W;
appropriate equations of state for this adiabatic process are provided in Section 1.17. Finally,
one
should
note
the
need
for
correspondence
between the independent variables involved in the specification of dE and dW; both must be formulated internal
coordinates.
If
dW
also
in terms of changes
includes
any
changes
of in
potential energy that leave the internal coordinates unaltered, then this quantity must be correlated with dU, where U is the total energy of the system.
These matters are illustrated
in
Chapter 6. Another
instructive
exercise
consists
free expansion of a gas, depicted initially totally opened
confined
to a space
evacuated.
A hole
in the diaphragm
in Fig.
of volume the
involved
in
this
straightforward"
process? If
encompassing only the
the
The
two volumes;
system
volume VA,
answer is
V B being
dimensions
ultimately occupies the total volume V^ + V B. is
taken
the
The gas is
VA, volume
of macroscopic
separating
in examining
1.8.2.
is now the
gas
What is the work not
absolutely
with
boundaries
complications arise because
60
I. FUNDAMENTALS
vA
VB
FIGURE 1.8.2 Schematic diagram pertaining to the free expansion of a gas. The gas is initially confined in compartment A of the system and is allowed to expand into compartment B through a hole opened in the diaphragm separating the two regions.
in the expansion process the internal coordinates of the system so defined the hole.
are altered,
in
of the motion
of gas
through
With respect to the system of volume V A one now deals
with an open system, up
because
Section
encompasses
with new ground rules
1.23.
If,
on
the
that will be taken
other
hand,
system
the total volume V A + V B plus the inside portion of
the walls,
no work is executed by the process.
this point
it is important
system
its
in
the
equilibrium
original
state.
to restrict
equilibrium
To understand
considerations
state
and
There has been no change
in
to the
its
final
in surroundings,
nor has any work reservoir been needed to run the process. differently, within
the process
the completely
of expansion has taken place
isolated compound
or work crosses the boundaries.
totally
system A + B; no heat
It is worth noting again that
there is no need to worry about the complex interactions jets
of expanding
gases
exert
Put
forces
first in one direction as they emerge
on
the
container
as the walls
from chamber A and then
in other directions as they strike the various walls of chamber
THE FIRST LAW AND THE CONCEPT OF HEAT
B.
The
final
state
of
6 I
the
system
is
reached a totally quiescent state,
that
in which
it has
and AE for the process
of
reaching this final state from the initial state, vanishes. As yet
another
example,
suppose
head to drop under the earth's adiabatic enclosure.
one
allows
gravitational
a cylinder
field inside an
A gas initially at pressure Pi is being
compressed in this process.
The cylinder ultimately comes to
rest
pins.
on
a
set
of
retaining
The
change
in potential
energy of the cylinder head has been transmitted in part to the walls and to the retaining pins and in part to the gas which is being compressed, by
so that only a portion of the work performed
the externally
gas.
applied
This has serious
field has been
transmitted
to
the
implications with respect to the work
concept and would indicate that performance of work is affected by
the
opposing
circumstances
internal
the work
pressure
of
the
should be written
gas.
In
these
in the form mgdz
-
in conjunction with
a
PidV. The
fallacy
of
this view
concept of adiabatic processes. partitions from
which
the
separate
remainder
of
arises
Adiabatic enclosures are ideal
regions
of
thermodynamic
the universe;
interest
in particular,
no
transfer of any type can occur across those boundaries. present
example,
however,
the walls
of the container
are
intimate contact with the gas which is being compressed. these
walls
cannot
be
considered
as
part
of
the
heat
In the in
Thus,
adiabatic
partition which separates the container plus contents from the remainder of the universe. Note slammed
further that the final state of the piston having
into
the
arrest,
is
not
an
equilibrium
state :
temporarily the piston, walls, and arrests are at temperatures different various
from
that
subsystems
of
are
the
gas;
in different
the final system of the assembly. between until
the the
calculating initial
inside
adiabatic
equilibrium work
state
performed,
equilibration
at
state
the
time
of
impact
states which differ
the from
Heat exchange will now occur
walls
and
arrests
develops. one
must and
For thus
end
and
the
gas
purposes
of
start
with
with the
the final
62
I. FUNDAMENTALS
equilibration state.
The fact that the system passes
intermediate
wherein
potential does
stages,
energy
not
of the piston
matter:
irrelevant
in
not
Details
are
of
thermodynamic
all
of
the
communicated
the
intervening
analyses
through
alterations
based
to
the
in gas,
processes on
are
equilibrium
states. The above
examples
illustrate
the necessity
of dealing
appropriately with the concept of work and with the placement of boundaries which delineate a system. one
must
distinguish
perturbations surroundings, a process
that
carefully
affect
the
Concerning the former,
between
system
or
work the
state
it is completed,
boundaries
the
must
be
such
that
no
The placement
frictional
or
other
effects occur in the immediate vicinity or across
the boundary; be
of
and the work
involved must be calculable by standard methods. of
other
one must deal with a system at equilibrium before
is started and after
dissipative
and
clearly
regions
included
surroundings.
One
in which such phenomena take place must either should
in
the
note
system
again
or
that
else
in
the
changes
in
the
specification of the boundaries may totally alter the work that accompanies a given process. (e)
It may not be
out of place
to provide
illustration concerning the concept of work.
one
further
Consider a point
of mass m attached by a weightless spring (See Exercise 1.8.10, which deals with changes
required
mass)
This
to
a rigid wall.
1.8.3.
Note
system,
which
that will
the
spring
later
if the spring
situation
is depicted
and mass
point
placed
in
be
itself has
in Fig.
constitute contact
mechanical work reservoir through which mechanical
a
with
the a
forces may
be exerted on the mass point and spring. Initially the spring is in an equilibrium configuration; in the absence of any net force length x -
x o.
it is extended
to its normal
In this initial state the force exerted on the
mass point by the spring and by the surroundings both vanish" msprlng m F - 0 and Fsur m Fexc - 0.
Furthermore,
the mass point
M remains stationary at x = Xo; its velocity is v = O.
Now
THE FIRST LAW AND THE CONCEPT OF HEAT
6~
~F I~!
X~
FIGURE 1.8.3 Schematic attached mass point.
apply an external so that F spring.
diagram
compression
xo) , and that the force F points x.
quasistatically, infinitesimal for
the
massless
- xo), where k is the force
that under
(increasing)
of
X
spring
with
force on M, assuming that Hooke's Law holds,
- k(x
Note
~
Let such
constant
(extension)
force
that v m 0;
compression
The w o r k done by the mechanical
x < x o (x >
in the direction of decreasing
this
first
then
be
Fext -
or
exerted
- F.
excess or deficit of IF,xtl relative
quasistatic
of the
expansion
Only
an
IFI is n e e d e d
of
the
spring.
reservoir on the spring is then
given by
W-"
~~o F e x t . d+x -_
~1
_F'dx--_
~1
0
where
x I is the extension
final
value
adiabatic the
-
is
located
given
This
stored
is compressed
leads by
spring
x I.
Note
to the
final
AE-
energy
in the
at
of the
hk(x I
difference
spring,
that
appears
its
in
result
- xo) 2
no matter
to
if
an
that k
is
as
the
whether
the
or extended.
let external
to counter
(compression)
(1.8.4)
is
x.
energy
Next, needed
of
M
Eq.
change
independent
spring
which
process
energy
potential
at
(I.8.4)
k(x_ - x0)-dx,_
0
force be applied
the force of the spring.
- F + Fa, where F a is the excess force.
in excess of what is We now set up F,x t Note carefully
that
64
I. FUNDAMENTALS
the
definition
context,
Eq.
(1.6.1)
still
applies
in
the
present
but now
O
The first
term is treated just as before,
-
The
Xo) z.
resulting -
second
first
in W reads
reaches
law,
(d2x/dt2).dx-
W--
reflects
from the u n c o m p e n s a t e d
0 at x - x o and
Newton's
term
F-
~k(x~
the
force F a.
- md2x/dt 2.
( d v / d t ) . v d t - v-dv.
Let
- v;
- x0) 2 - h m ~ ,
first
term
is (1.8.7)
is
clearly
term represents
the mass point because
then
(1.8.6)
energy involved in the elongation and the second
to
the second term
AE - hk(x I - Xo) 2 + h m ~ , the
is X
According
dx/dt
M
(1.8.5) becomes
and the energy change of the system
where
of
The v e l o c i t y
Accordingly,
Then Eq.
- h(x I
acceleration
X - vl at x - x I.
ma
- hm(v a - 0).
yielding W -
the
increase
in
or compression
the kinetic
the outside
applied
potential
of the spring
energy
acquired by
force exceeded
the
force exerted by the system in the amount F a. The fact
that
replace
foregoing only
is a very
in quasistatic
elementary processes
illustration
is it permissible
the externally applied force by an oppositely
internal force.
If this can be done the internal
Proper
is invited
to work Exercises
on his or her u n d e r s t a n d i n g thought
delineate
should
be
appropriately
surroundings consideration.
to
directed
amenable
to
1.8.5-1.8.10
to
analysis.
The reader enlarge
the
force becomes
a function of state of the system itself and thus, thermodynamic
of
in
any
given the
to
of the foregoing concepts. the
system
particular
problem as
physical
as
to h o w
opposed problem
to
to the
under
THE FIRST LAW AND THE CONCEPT OF HEAT
65
EXERCISES
1.8.1 On the basis of the First Law of Thermodynamics, show that for the sake of consistency with the conventions adopted in the present section, it is necessary to define the element of work for moving a system through a height of dz in the earth's gravitational field as -M, gdz rather than +M, gdz. Repeat the argument for the electrostatic case where one may write ~W r - Q d ~ . What is the corresponding expression where a system is subjected to a magnetic field? 1.8.2 Discuss methods of determining changes in the internal energy of a system which do not rely on measurements of work carried out adiabatically. I. 8.3 A 2 :1 mixture of H 2 and 02 gases was ignited and exploded in a bomb of constant volume and the temperature rose 20 ~ before any energy had time to escape. What are the values of Q, W, AE? Discuss the reasons for your findings. 1.8.4 A I00 g lead ball at 27~ is dropped from a height of i0 m. (a) Find the kinetic energy and speed of the ball just as it reaches the ground. (b) Find the temperature rise of the ball is all of its kinetic energy is transformed into internal energy as the ball is suddenly stopped after I0 m, given that the specific heat Cv of lead is 0.03 cal/deg-g and assuming that its volume change is negligible. [In anticipation of later results, note that AE = CvAT ] . The constant of gravitational acceleration, g, is 980 cm/s 2. 1.8.5 Carefully consider the various signs attached to expressions for AE for the various processes described in subsection (d), and justify the presence or absence of minus signs for each case. 1.8.6 Consider a system consisting of a vertical hollow, adiabatically insulated tube to whose bottom is attached an inflatable, insulated balloon. Let a piston of mass m slowly move through a height h within the tube by the process of gradually adding sand to the top of the system, thus inflating the balloon. What is the final pressure relative to the initial pressure? The final volume relative to the initial volume? The work performed on the system if the latter is considered to be the gas within the enclosure? What has happened to the work performed by the plston-plus-sand? 1.8.7 A piston of cross section A moving horizontally in a hollow tube (adiabatically insulated) is propelled by a force F A against a gas held at constant pressure Ps < FA/A" What is the initial acceleration of the piston? How far is the energy of the gas raised after the piston has been moved a distance d? How much is the energy of the walls increased in this process? What can you say about the work transfer after the piston has been stopped and the entire system is allowed to equilibrate?
~6
I. FUNDAMENTALS
1.8.8 (a) Consider a fast irreversible expansion of a gas in an adiabatic enclosure which results in the upward motion of a piston that supports a platform onto which is bolted a weight of mass M v. The piston and support system is massless and slides upward without friction, until arrested by a set of stops. How much work is performed by the system if the total travel of the piston is over a vertical distance h? (b) The experiment is now repeated with the m a s s not bolted onto the platform. When the piston hits the arrests, the mass continues to travel vertically upward through an additional distance h' before reversing its motion. It is caught at that point and stored on a shelf. How much work has the system performed in this operation? 1.8.9 Consider again the experiment in which grains of sand are gradually added to and subsequently removed from a piston supported against gravity by a gas at pressure P contained in an adiabatic enclosure. Analyze the processes that occur, taking into account the frictional effects of the piston as it slides up and down the walls of the container. How does this situation differ from the case where frictional effects are assumed to be negligible? What effects does Irreverslbillty have? Consult Footnote 4 if necessary. 1.8.10 Two what extent must the discussion of Section 1.8(d) be modified if the spring has a mass of its own? Work out the detailed expressions. I. 8. II Explain why an equation of state cannot be derived on the basis of thermodynamic considerations but must be obtained by experimentation. 1.8.12 Use the well known Einstein relation to determine the energy in calories liberated when I tool of helium nuclei of mass 4.0028 are formed from two protons, of mass 1.0076 each, and from two neutrons, of mass 1.0090 each. 1.8.13 Using the well known Einstein relation check whether the change of mass inherent in a typical chemical reaction is experimentally detectable. As an exampe, select the combustion of on mole of sucrose for which the heat liberated is approximately 1.35 x I06 cal. 1.8.14 For each of the processes considered hereafter determine whether an ideal gas used as a working substance does negative work, positive work, or no work: (a) the gas contained in a balloon is cooled in an ice bath and the balloon shrinks, (b) the gas is placed in an rigid container and warmed in sunlight, (c) the gas is transferred reversibly from one rigid container to a second which is half its size; a piston is employed in the transfer.
4J.A. Beattie and I. Oppenheim, Principles dy~.amlcs (Elsevier, Amsterdam, 1979) Chapter 3.
of Thermo-
THE FIRSTLAW AS A PARABLE
67
1.8.15 Two what extent must the discussion of Section 1.8(d) be modified if the spring has a mass of its own? Work out the detailed expressions.
i. 9
THE FIRST LAW OF THERMODYNAMICS AS A PARABLE
Callen 5 has
provided
Thermodynamics
an
interpretation
of
the
Law
of
in terms of a parable that bears repeating.
A
certain man owns a rectangular swimming pool; to enter or to leave and and daily measures
First
he allows water
the height of the
water level as a means of monitoring the volume of water. water inlets and outlets to the pool are
The
equipped with water
meters. The noting
owner
can
the height
now
check
in the water
volume change of the water,
on
conservation
level,
of
computing
water
thereby
by the
and comparing result this with the
water meter readings at the inlet and outlet.
In general the
owner finds no correlation that is immediately evident, but he notices
that on rainy days
anticipated
the pool contains
from a balance
more water
of inflow and outflow
than
through
water meters, and on very dry days the pool contains less.
the So,
the owner eventually is led to cover the pool with a tarpaulin; at
this
changes
stage
he
notices
that
in the amount of water
he
can balance
precisely
in the pool with the rates
the of
water passage through the inlet and outlet. The analogy with the energy of a system should be fairly clear.
The pool covered with a tarpaulin
adiabatic energy.
system;
changes
Water
flowing
is analogous
in water level represent changes through
the
inlets
and
represents negative and positive work, respectively. tarpaulin removed
is
removed,
through
the
evaporation
water is
added
through
analogous
to
negative heat flow in a diathermic system. a water balance
to an
cannot be achieved unless
expanded so as to keep track of changes
outlets When the
rainfall
a positive
Thermodynamics
or and
In the latter case the bookkeeping
is
in pool level arising
from the rainfall and evaporation processes.
5H. B. Callen,
in
(Wiley, New York,
1960).
~8
I. F U N D A M E N T A L S
Notice water;
one
finally cannot
that
the
water
differentiate
in
the
between
collected from the rainfall and that which pool
via
the
contention
inlet.
in
manifestations the system,
the
This earlier
of energy
should
in transit
more Heat
across
but are not identifiable
is
simply
liquid
which
was admitted to the
make
section:
pool
the
plausible
the
and
are
work
the boundaries
of
as two types of internal
energy contained within the system. All parables, and
to
some
parable
being analogies,
extent,
misleading.
are to be explored
are by necessity The
in Exercise
inexact,
shortcomings
of
this
1.9.1.
EXERCISE
1.9.1
I.i0
Discuss
the shortcomings
of the above parable.
THE CARATHEODORY APPROACH TO THE SECOND LAW OF THERMODYNAMICS :
PRELIMINARIES
We have seen in Section 1.8 that under suitable conditions
the
performance
the
energy.
of work can be related to a function of state,
The
question
arises
whether
a similar
option
exists
for the transfer of heat, again under suitable conditions. answer is in the affirmative; unfortunately, is not so easily demonstrated.
The
the correspondence
A fair amount of mathematical
groundwork must be laid to establish the link between heat flow and a new
function
mathematical
of state.
converts
differential termed
the
proceed
not
interested
in the
niceties can assume the implication of the Second
Law of Thermodynamics, which
Readers
the
through empirical
namely that there does exist a function inexact the
differential
relationship
entropy
dQ/A-
function.
The
to Section 1.13, beginning with Eq.
dQ
into ds,
We now begin with the more rigorous
where
reader (1.13.1),
loss of continuity. analysis.
an
can
exact s is then
without
THE
FIRSTLAW AS A
(a) The here
69
PARABLE
for
discussion
use
in
Thermodynamics.
of
Section
conjunction
1.4 will
with
the
be
generalized
Second
F.u.nctions o.f state of interest
Law
of
are analytic
relationships e of the form
R-
(z.io.I)
R(xl,...,xl,...,x~),
in which the dependent variable R is uniquely prescribed by the values
of the independent variables
x i which characterize
thermodynamic properties of a system. differential
the
The corresponding linear
form is given as
n
(1.1o.2)
dR - ~. (8R/ax i) xj~idxl. i=l In thermodynamics linear differentials
we have
frequent
occasion
to examine
of the type
n ~L " ~ X i(xl,...,ym)dxl, i=l which
resemble
Pfaf.f.i.an state,
Eq.
forms.
(i.zo.3)
(1.10.2);
If
it
these
so happens
quantities that
L
is
are a
then (I.i0.2) and (I.I0.3) are equivalent:
interchangeable,
known
as
function
of
L and R are
subject to the definition X i ~ 8R/Ox i. On the
other hand, ~L may not be the differential of something;
~L is
then simply a shorthand notation for ~(1)Xidxl, and the X i are no longer
partial
quantities
derivatives
are
not
of
directly
a
function
useful
in
of the
state.
Such
thermodynamic
characterization of systems of interest. (b)
If a given
differential possible,
of
the
quantity form
under conditions
L does
(1.10.2)
not
it
constitute an exact differential. are of special
6Nonanalytlc
points.
may
of
properties
an exact
nevertheless
to be established later,
a function q(xl,... ,xn) with the property such a property
admit
be
to specify
that ~L/q ~ dR does
Pfaffian forms that display
interest;
they are said to be
are allowed at isolated singular
70
I. FUNDAMENTALS
holonomlc or inte_~rable; otherwise they are nonholonomic. obvious
reasons
For
I/q is termed an inte_gratln~ factor and q, an
integratln~ denominator. _
w
(c)
The particular
equation
n
(1.10.4)
~L - ~ Xldx i - X.dx - 0 i-1 is of special
interest.
Eq.(l.10.2)
applies,
equlvaleDt
of the form
R(x~,...,x~)
If it is an exact
~L-
the
x,.
and
there
exists
(1.10.5) Recall
a hypersurface If
~(1)Xldxl
(Section 1.4) that Eq. (1.10.5)
in the dimensional
is
nevertheless holonomic, such that q d R -
not
an
exact
space spanned by
differential
but
is
then an integrating factor may be found
Z(1)Xldxi, whence
X i(x i,...,x a) - q(x 1,...,xn)(aR/axl)xj~i. Further,
then
an algebraic
- C,
where C is a constant. represents
dR,
differential
relation
(i. I0.4),
(1.10.6)
~(1)Xldxl -
0,
then
implies
that
(l/q) ~(1) Xldxl - 0, and hence, dR - 0, thereby establishing the existence of an algebraic equivalent
(I. i0.5) to Eq. (I. i0.4).
It is necessary here and later to distinguish carefully between the
Pfaffian
form
~L
diffe, rential equation
-
Z(1)Xidxl
and
the
corresponding
~(1)Xldxl - 0.
(d) By analogy to Section 1.4(g), any particular solution of the differential the hyperspace additionally are
equation Zci)Xidxl-
R n spanned by the
0 forms a curve c n in
'coordinate
the Pfaffian form is holonomic
functions
of
8R/ax i by
(1.10.6),
may
of
the
function
R.
Similarly,
the
{xi}.
If
then the X•
which
be
of
components of a vector X which is proportional VR,
axes'
thought
as
to the gradient,
various
dx i may
be
considered as components of the displacement vector dx m {dx i}.
THE FIRST LAW AS A PARABLE
Finally,
7 I
again by extension of the discussion of Section 1.4,
the algebraic equivalent R(xl,... ,x=) - C may be represented by a hypersurface ~= in R=. Now since VR is everywhere orthogonal to the surface R C, X is always in the direction of the normal to the surface of ~n"
The requirement
(i. i0.4),
met by having dx perpendicular to the surface R - C .
abbreviated
as X-dx- 0, may be
to X, i.e.,
everywhere
Therefore,
solution curves C n to X . d x -
0, formed by adjoining the various must
lle
Finally, of
entirely
on
the
tangent
infinitesimal
surface
~n
segments dx,
defined
by
(I.I0.5).
it should be evident that there exist a vast multitude
points
(1.10.4),
in
Rn
not
accessible
by
solution
curves
Cn
of
namely all points not lying on the surface ~n.
All of the above geometric imagery is of great importance to the formulation of the Second Law which is to follow. (e)
We
holonomlc
have
and
sufficient
if
so
far
(i. I0.4)
to guarantee
demonstrated
that
if
holds,
these
conditions
that
then
in any neighborhood
point x= in R n there exist other points surface
~n
accessible
corresponding
(1.10.3)
to
Eq.
are
of a given
[namely those not on the
(I.I0.5) ]
which
are
not
from x via solution curves of X-dx - 0.
Is the converse also true;
i.e.,
from the assumption of
nonaccessibility can one deduce that ~(1)Xidxl is holonomic? affirmative
is
answer is provided by Carath4odory's
If every neighborhood a hyperspace
contains
An
Theorem"
of an arbitrary point x= in points
x not accessible
from
x o via solution curves of the equation ~(1)Xldxl - 0, then
the
Pfaffian
form ~L-
~(i)Xidxi i s h o l o n o m i c .
The proof of this important theorem which establishes the necessary Appendices, interested assume
conditions given in
the
in
for
holonomlcity
Sections
mathematical
its correctness,
i.ii
niceties
and hence,
inaccessibility and vice versa.
and
is
provided
1.12. of
in
two
Readers
not
this
proof
that holonomicity
may
implies
The stage is then set for the
7~
I. FUNDAMENTALS
statement Section
i. II
of
the
Law
Second
of
Thermodynamics
provided
in
1.13.
APPENDIX:
MATHEMATICAL
OF THERMODYNAMICS.
Before p r o v i d i n g
a proof
PREPARATIONS
FOR THE SECOND
LAW
HOLONOMICITY
of Carath~odory's
Theorem we digress
to specify necessary and sufficient conditions for e s t a b l i s h i n g whether
the Pfafflan
form ~ L -
We first prove variables
~(1)Xidxl is holonomic
that any linear differential
is integrable:
or not.
form in two
given
~L -- Xldx I + X2dx2,
(1.11.1)
we seek a function q(xl,x2) such that ~L/q = dR, where dR is an exact differential;
BL-
i.e,
qdR,
(1.11.2)
dR-
(aR/axl)dxl + (aR/@x2)dx 2.
(1.11.3)
From
(I.II.I)-(i.ii.3)
where
we require
(1.11.4)
Xldx I + X2dx 2 - q (aR/axl) dXl + q (OR/ax2) dx 2 , which holds
X I
-
for arbitrary
q(SR/Sxl),
X2 -
dx I and dx 2 if and only if
q(aR/Ox2).
(1.11.5)
These two relations can in principle always be solved for q and for R; X I and X 2 are known functions
x~
(aR/ax~),~
lax2]
X2
(OR/Ox2)x 2
[OxJ x
of x I and x 2. Thus,
(1.11.6)
7~
APPENDIX: MATHEMATICAL PREPARATIONS FOR HOLONOMICITY
as
is
consistent
displacement
with
vector
(1.11.3)
and
(I.ii.I).
components
are
related
Note to
how
one
the
another
t h r o u g h X I and X 2. We
conclude
integrable
that
since
if one were
the
(1.11.5)
to examine
Pfaffian
specifies
form
(i. II.i)
q as well
a sum of three
terms
to a d j o i n
r e l a t i o n X 3 - q(aR/Sx3).
It is then no longer
q(xl,x2,x3)
and
a
second
(1.11.5)
function
as R.
However,
the a d d i t i o n a l clear w h e t h e r
R(xl,xg,x3)
found that s a t i s f y all three X i - q ( S R / a x i) equations. we shall n o w address
(b)
In
q(xl, . . . ,Xn)
ourselves
precisely
the
more
general
case
such
that
(I/q)WL
-
R(xl,... ,Xn) is a f u n c t i o n w h i c h a total d i f f e r e n t i a l n
dR-
We
can
a be
In fact,
to this question.
one
dR
always
as Xldx I + X2dx 2 +
Xsdx 3 - ~ L one w o u l d have
function
to
is
or
does have
seeks
a
~L
qdR,
where
(in c o n t r a s t
to ~L)
-
function
of the form n
7. (8R/axl)dxl " 7. Yidxl. i-i i-i now
examine
(1.11.7)
the n e c e s s a r y
conditions
that m u s t
be met
for
this scheme to work.
If indeed the f u n c t i o n q w i t h the d e s i r e d
properties
found
(i. II.7)
has
shows
been
then
comparison
of
~L
qdR
with
that
(1.11.8)
Xl - qYi - q(aR/axl)
m u s t hold.
-
For the m o m e n t c o n s i d e r
the special
case w h e r e n -
3, so that
(8R/axl)
- YI - X j q ,
(8R/axa)
(8R/ax2)
- Y2 - X2/q,
(1.11.9)
" Y3 = Xa/q.
Since the order of d i f f e r e n t i a t i o n find
a
(I.II.9)
relation
between
according
any
two
of
to the f o l l o w i n g
the
is immaterial, functions
procedure:
we can
listed
in
~4
I. FUNDAMENTALS 8ZR
8Y1 I
8x28xl
8xz
aYz
- a~
The
1
8X1
X1
8q
q
8xz
q~-
8x2
8ZR
(1.11.1o)
I
I 8X~ - 8 a~
central
and
X " ~
last
8xlSx2
aq a~"
term
in
the
above
sequence
can
be
recombined to obtain
pX
q [.~x2
-
8Xz} 8xl
-
X1
8q 8xz
-
Xz
8q 8xl
(1.11.11a)
Using similar procedures for the remaining second partials of R, one finds
pXa q L~xl
.
8XI "I 8xa
SXz 8Xa} q[axs'-'7-- 8xz
.
X 3
8q cqxl
-
X I
8q 8xa
(l.ll.llb)
-
Xz
8q 8xs
-
Xa
8q 8xz
(l.ll.llc)
Now multiply both sides of (l.lla,b,c) by X3, X2, and X I respectively and add the resultants. found to vanish identically,
The rlght-hand side is
as a result of which the common
factor q on the left may be dropped.
x~t~
-
~j
+
x, 6E
-
ax.
+X
This leaves
3
6~
-
7xj
-
0
"
(1.11.12) We see,
then,
that if an integrating factor I/q exists
that converts the Pfaffian form ~L, into an exact differential, Eq.
(i. II.7),
then the coefficients
X i in the relation ~L -
X1dx 2 + X2dx 2 + Xadx 3 must obey (1.11.12). The latter relation may readily be generalized to the more general case n > 3, by replacing the subscripts i, 2, 3 in Eq. (1.11.12)with i, j, k, respectively.
APPENDIX: MATHEMATICALPREPARATIONSFOR HOLONOMICITY
(c) We n o w
seek
Given a Pfaffian
form
to prove
75
the
inverse
of the
foregoing:
n ~L
X~dx~,
- Y~
(1.11.13)
i-i in w h i c h we
the X i obey
prove
factor linear
that
(1.11.12),
there
I/q w h i c h
the
+
Xndxn ;
demonstrated
well
form
Eq.
is
(a).
a total
as an i n t e g r a t i n g
indices
exist
an
~L
let
then
one
a
first the
form
integrable
as
was
must
be
able
form
to
find
(1.11.7),
a as
such that
(1.11.14)
(xl,... ,xn_2 constant).
form Xn_ I and X n are b o t h
likewise
hold
to
of the
~,
us
reduces
certainly
denominator
of all x i, ~ and H will
into
(1.11.7).
Thus,
in their most general
i, J, k,
integrating
differential
(1.11.13)
differential
Xn_Id~_ I + Xndx n - ~ d H
Since
inexact
(i. Ii. 13)
this
in part
function H with
the
always
of the form
Pfaffian
xl, . . . ,xn_2 constant; Xn_idxn_ I
then
converts
differential In
will
with cyclical
depend
functions
on x 1,...,xn_ 2,xn_ 1,x n.
If we n o w relax the c o n d i t i o n on xl,...,xn_ 2, then we must w r i t e n dH - ~ (8H/axl)dx i. i-I To
go
back
(1.11.14)
from
(i.ii.15)
(1.11.15)
we replace
to
the
the r i g h t - h a n d
more
restrictive
side
in (1.11.14)
condition as s h o w n
below"
Xn_ldXn_l + Xndx n - ~ dH -
(1.11.16)
(@H/Bx i)dx i , i-I
w h e r e we have n o w d r o p p e d the r e s t r i c t i v e (1.11.14), been
because
effectively
right.
The
differential
dH form
the effect 'subtracted
appearing (I. ii. 15).
in
c o n d i t i o n r e q u i r e d in
of the v a r i a b l e s out'
by
the
(I.ii.16)
xl,...,xn_ 2 has
second is
the
term
on
the
full-fledged
76
I. FUNDAMENTALS
C o n s i d e r next the P f a f f i a n
form (1.11.13),
rewritten
as
n-2 Xtdx i + Xa_Idxn_1 + Xadx n - ~ L
(i.ii.17)
i-I and substitute
from (1.11.16).
O[x
This yields
for d L -
0
}
t/~ - (8H/Bxt) dxt + dH - ~L/~ - 0.
(1.11.18)
i-I
At this stage it is convenient Yt -
xt
for
(i-
1,2,...,n-2,n)
and
This makes Yn-1 a function of all permissible
operation.
Then Eq.
set
Yn-1 "
xt, but this
Furthermore,
for i - 1,2,...,n-2.
to switch variables.
H(xl,.-.,Xn)is a p e r f e c t l y
set Yt " Xi/~
(I.ii.18)
Let
- (SH/axt)
takes the form
n-2 Ytdyt + dyn_ I - ~L/~ - O,
(i.ii.19)
i-i
containing however, entire
one
fewer
differential
than
does
(ii. Ii. 17) ;
the Yt at first glance w o u l d all seem to depend on the
set of variables Since
we
have
Yl, 9 9 9 ,Yn-
passed
algebraic
transformations
integrable
if and only
from the
(1.11.17) former
if the latter
to
(1.11.19)
equation
is.
by
will
be
By hypothesis,
Eq.
(1.11.12) applies to (1.11.17); hence, a c o r r e s p o n d i n g e q u a t i o n will have
to h o l d relative
8Yj
Yt [By k " 8yj Now
+Yj
8Yt/ay= - 0
+Yk [8~y~
specifically
(1.11.19),
to (1.11.19),
set j - n
8y k
namely
PaYt
8Yj ] -
ayj
- i, k - n.
-
0.(i.
11.20)
ayl
Since,
according
Yn-1 " I and Y= - O, the above e q u a t i o n reduces (all i),
w h i c h shows that,
to to
(1.11.21)
in fact, none of the Yi in (1.11.19)
depends
APPENDIX: MATHEMATICAL PREPARATIONS FOR HOLONOMICITY
on Yn.
Thus,
Eq.
Yl,''', Yn-l" We now
(1.11.19)
repeat
the
77
involves only the n -
entire
process
I variables
beginning
anew
with
(1.11.14); each time we do so we arrive at a form equivalent to (1.11.19) variable
which than
can be
its
demonstrated
equivalent,
Eq.
to
depend
(i. Ii.17).
on
one
fewer
In
the
final
iteration the analogue of (1.11.19) contains only two variables and
thereby
definitely
becomes
integrable.
Thus,
we
have
demonstrated that the original equation (1.11.17) is integrable if Eq.
(I.ii.12) holds. In view of the above development,
to be
both
a necessary
and
a
Eq.
sufficient
(1.11.20)
is found
condition
for
the
integrability of the Pfaffian form (I.ii.13).
EXERCISES
i. Ii.i Which of the following forms is holonomic? Find integrating factors for those which are holonomic. (a) (3xZy y)dx + (3x + x)dy, (b) xdy - ydx, (c) ydx - xdy + yZxdx, (d) y z d y - zydz. 1.11.2 Consider the relation d L - R(r).dr If dL is an exact differential prove that dL is the diff4rential of a scalar function F(r) satisfying the relation R(r) - V.F(r) and show that the necessary and sufficient condition for existence of a gradient of a scalar function is that it be irrotational" V x R - 0. Show that this latter requirement coincides with the necessary and sufficient conditions rendering ~L an exact differential. 1.11.3 Show that if there exist a scalar function G(r) v such that V x (GR) - 0 then the relation d L R(r).dr Is holonomic. (This may be most readily accomplished by examining R-V x (GR) and noting what happens when this quantity is forced to vanish with R, G ~ 0.) 1.11.4 (a) Is the linear differential expression 3yzdx + xzdy + 2xydz an exact differential? (b) Show that x2z is an integrating factor for the foregoing expression. (c) Show that x2z(xSyz 2) is an integrating factor. i. Ii.5 What is the geometric interpretation of the quantity y d x - xdy? [Hint" Make the transformation to cylindrical polar coordinates x - r cos 8, y - r sin 0. ] Find an integrating factor for ydx - xdy.
"~
I. FUNDAMENTALS
1.12
APPENDIX:
M A T H E M A T I C A L PROOF FOR THE N E C E S S A R Y CONDITION
OF CARATHEODORY' S THEOREM
In
Section
sufficient
i. I0
we
conditions
We establish also
had
provided
arguments
establishing
in regard to Carathdodory's
Theorem.
in this Section that Carathdodory's
formulates
a
necessary
statement,
by
Theorem
proving
the
following:
If in every n e i g h b o r h o o d defined
by
the
set
of any point
(x)i,
i -
in the space
l,...,n,
there
are
points
that are inaccessible along solution curves n of the equation.~ Xidx i - O, then the c o r r e s p o n d i n g
Pfaffian
forml--~L
-
~(1)Xldxl
is
necessarily
integrable.
As
is
well
known,
a
curve
C
in
a
hyperspace
may
be
defined as the collection of all points generated by equations of the form
x i - fi(u)
(i-
where the fl are specified, valued
functions
correspond parameter
to
(1.12.1)
1,2,...,n), continuous,
of a parameter the
choice
of
such that u a _< u _< u b.
intersects
C
at
infinitesimally
u
-
from C.
u,
and
u. two
differentiable, Let
the points
specific
single-
Pa and Pb
values
of
the
Let C a be another curve w h i c h which
otherwise
differs
only
Then C a may be specified by equations
of the form
xl - fi(u) + ~41(u)
(i = l,...,n),
in which
~ is a small
function
analogous
41(u,) ~ 0
positive
quantity
(1.12.2) and ~i(u)
is another
to fi(u), with the constraint
(all i).
(1.12.3)
APPENDIX: PROOF FOR CARATHI~ODORY'STHEOREM
Moreover, curves,
since
C
"79
and
C a are
defined
they must satisfy Eq. (i.i0.4),
to be
solution
i.e.,
n im
(1.12.4)
Xi(xl)fi(u) - O, i-1
where
we
shall
emphasize
the
write
Yi(u)
- Xi(fi(u))
whenever
we
want
to
dependence of the specified X i functions on u.
The same condition must apply to the displaced curve" n
(]..].2.5)
7. Xi(fi(u) + e41(u))[f[(u) + '4'i(u)] - 0. i-I
We write out (1.12.5) by expanding the arguments of the X i in a Taylor's series in all the 41, keeping only terms of order ~0 and ~I. This yields n
(1.12.6)
Z Yi(u)[f[(u) + ~4[(u)] + i-I n n [0Xll
+Z
Z
i"'-i J-i
~0(u)
I,.~jJ
On account of (1.12.4), n
n Z
Xi41 +
t-t
n ~
fi
'(u) - 0
9
(1.12.6) simplifies to
(1.12.7)
(0xl/axjl4jf [ - 0.
t-].j-1
Equation
(1.12.7)
may be satisfied by choosing n - I of the
functions ~j arbitrarily and requiring the last, ~n, to conform to the requirements of (1.12.7). of this statement,
Xm ~n +
~ pXi]
t-1
rewrite
n-I
j -i
To examine the implications
(1.12.7) as n
x~
t-1
n-i p X • I j-1
f'i~0.
La~xjj
(I 12 8) "
"
The first-order differential equation may be solved by seeking a function A(u), with which both sides of (1.12.8)
are to be
~
I. FUNDAMENTALS
multiplied, such that this will convert the left-hand side into the differential
d(lYn~n) du
i AXn~ n + I E i-I
Comparison
of
finn + A'Xn~n"
(1.12.9)
with
the
(1.12.9)
left-hand
side
of
(1.12.8)
multiplied by A shows that if an identity is to be obtained, then A must satisfy the relation
;~, _x~il ~ [ax~ ax~] ,
(1.12.1o)
i-1 [8xn " 8-xxi fi-
Now multiply both sides of (1.12.8) by A and introduce (1.12.9) to eliminate X,4 n.
Also, eliminate A' in the intermediate step
by use of (1.12.10).
Integration of the resultant expression
leads to
~x,~,,
-
-
i
~
xa~ a +
9
I
n pX,]flea]du
~
j-I~-i ta-~TaJ
1
(i 12.11) "
'
where (1.12.3) has been used on the left. Next,
we examine
the first
integral
on the right
and
carry out an integration by parts. n-I - [a ~
n-i A ~Xj~ a
Y Xa~,~ d u - j-1
+
n-I
+ ~ua A' ~ Xj~j
j-1
du
j-z
fan-i
n
[8Xj1
g
I
ta-~-j f;~jdu,
.I-i
~-i
(1.12.12)
where (1.12.3) was again applied in obtaining the first step on the right, and (1.12.1) was introduced to obtain the last term. Now substitute Eq. yields
(1.12.10)
for A' in (1.12.12);
this
APPENDIX: PROOFFOR CARATH[:ODORY'STHEOREM
n-i
8 [
n-i
. [ax. a~ ]
nn-i
I ~ j -r.1 x~,;~u- - ~ j -r~1 x~,~. ~ ~ ~.
-
I E ~-D-1
--..
+
fi~j [ a ~
o
- -
Xj
OXi
(1.12.13)
du, axl
This
is
now
ready
to
be
substituted
into
(ii.12.11) ;
on
simplifying one obtains
. nn r]
~.--I
~j-
I
[x,{;x ,x.I Lastly,
observe
)
I
x
~
fox.
that
on account
(1.12.14)
of
(1.12.4)
one may
add
the
te rms
without altering equation
(1.12.14)
in any way.
This yields,
finally,
n-I Xj~j(u) ~.(u)
-
-
I
j-I
-
Xn
i
n
AX n
~
n-I ~ ~
f'i~j(u)
Ju,
Fi3n du, (1.12.15)
in which
Fijn
defines
the left-hand side of (1.11.20) with Y
X and y ~ x. Now examine
(1.12.15)
limit in the integral.
after setting u - Ub as the upper
Observe that ~n(Ub) on the left depends
not only on all ~j(Ub) occurring in the first term on the right but also on the values
these ~j take over the entire
u a _< u _< u b within the integral on the right.
interval
It follows
that
8~-
I. FUNDAMENTALS
one can choose the arbitrary functions ~j(u) that
from
the point Pa one can reach
neighborhood,
in such a manner
any other point
by choosing u b sufficiently
close
in its
to u a and by
permuting
indices so that all n functions ~j are successively
assigned
the
hypothesis;
we
neighborhood from Pa.
terminal started
n.
But
out under
of Pa there were
this
is
contrary
the assumption
points which were
that
to
in the
inaccessible
The only way to avoid the impasse is to cause all the
integrals to vanish; attempting else
index
clearly, we should not accomplish this by
to set l, ~j, or 1/X, equal
would
be
lost.
However,
we
to zero,
can
achieve
for then all this
goal
by
setting n l
(1.12.16)
Fij,fi - 0; i-i for,
in that event 4n(Ub) depends
only on the specific values
which the n - i arbitrary functions 4j take on at the point u - u b.
This
clearly limits
the number of curves which
constructed to pass through Pa, and hence restricts
can be
the number
of points Pb that can be reached from Pa. l
From (1.12.16) it is clear that either we must set all fl equal
to
zero
or
else
all
Fijn must
vanish.
The
former
alternative is unattractive because it places a restriction on the set of functions fl which should have been left arbitrary; hence
we
must
discussion
require
of Sections
instead
that
all
I.i0 and I.ii
Fijn E
it follows
0.
From
at once
the that
n
iZiX~dxl - ~ L
is integrable.
This proves the second part of the
Carath~odory statement :
If in the neighborhood of a given point others are n inaccessible along a solution curve of i_ZiX• 0, then
this
represents
both
a
necessary
and
a
sufficient condition for the integrability of the corresponding differential Pfaffian form. This completes the mathematical background exposition required for the Second Law.
THE SECOND LAW OF THERMODYNAMICS
1.13
The
~3
THE SECOND LAW OF THERMODYNAMICS
discussion
certain
of the
sense,
Second
analogous
to
Law
of Thermodynamics
that
of
the
First
is,
Law.
in a
We
saw
earlier that, under certain conditions, we could correlate with an
element
of
differential
work,
~W,
a
function
of
of the energy function.
state,
namely,
the
The question now arises
whether a similar step can be taken with respect to the element of heat transfer, ~Q, and if so, what kind of function of state corresponds
to it.
To preserve
a reasonably
this problem will have to be addressed
in a rather
way, based on the discussion of previous On
the
experiments
basis
of
carried
out
the
outcome
on
logical
roundabout
sections.
of
systems
approach
a
of
vast
number
greatly
of
different
complexity the following law is established as an experience of mankind:
The
SecoDd
eve ry
L.a.w of Thermodynamics
ne i ghbo rhood
adiabatically
of
isolated
any system
states that are inaccessible
The
above
Carath~odory's adiabatic in
the
immediately
an
exist
other
from S.
for
are inaccessible
differential
in
S
theorem to the equation ~Q - 0, which holds
form ~ Q -
to
there
in
of
systems.
According
s tate
that
application
leads
to
the
Since the heat flow is related
thermodynamic
Pfaffian
asserts
coordinates
~(1)Xidxl,
of
the
this means
system
to changes through
there are states
the that
from S along the solution curves ~(1)Xidxl - 0. the
discussion
form ~(•
i must
of
Sections
therefore
I. i0- I. 12
be holonomic,
the i.e.,
one must be able to find an integrating denominator l(xl,... ,Xn) such that
~Q/A - ds,
where ds is an exact differential
(1.13.1)
of a quantity
s, termed the
empirical entroov (function), which must be a function of state
84
I. FUNDAMENTALS
of the system. and for s;
It remains
two d i s t i n c t
systems
n o w relax the a d i a b a t i c f u n c t i o n of state of
as
function long
maintained.
the
function
adiabatic
state
s to the r e v e r s i b l e
and
by t
the
that w h e r e a s
of the
here
we
transfer
in
relate
under
all are
in the First
Law
the
of w o r k
function
of
of heat.
let two c l o s e d
A and
xl, .... Xn_1,t
contact,
empirical
let the t o t a l i t y of these c o o r d i n a t e s
systems
coordinates
diathermic
at a c o m m o n
set
conditions
E to the p e r f o r m a n c e
deformation
be
they are
to exist
Note
of the foregoing,
Yl, 9 9 9 ,Ym-1,
equilibrium
continues
equilibrium
conditions,
characterized
of
Note that we
once the e x i s t e n c e
as
of state
under
In light
the p r o c e s s
into a composite.
constraint:
said
conditions
we r e l a t e d
s o l e l y by
for A
(1.2.1) has b e e n p o s i t e d u n d e r a s p e c i f i c
circumstances,
appropriately
B,
an i n t e r p r e t a t i o n
this will be a c c o m p l i s h e d
combining
other
to p r o v i d e
so
that
temperature
characterize
at
t, and
the c o m p o u n d
sys tern C. Because surroundings
exchange
is additive,
involving
the
system
and
its
we find that
(1.13.2)
~QB.
~0~ - ~ 0 ~ +
Further,
any heat
from the h o l o n o m i c
character
of ~Q
it follows
that
(1.13.3)
ds c -- (AA/Ac)ds A + (AB/Ac)dSB.
Since s A and s B are functions of state they must d e p e n d on xl,...,xn_1,t and on yl...,ym_1,t respectively. can
invert
these
relations
to
solve
for
In p r i n c i p l e Xn_ I
in
terms
Xl,...,Xn_2,SA,t and for Ym-1 in terms of Yl,...,Ym-2,SB,t, shifting
SA and s B into the set of i n d e p e n d e n t
The
following
in its simplicity, elegant steps :
in
argument sweep,
science. [I]
sc
It
must
coordinates
xl, 9 9 9 ,Xn-2;
conjunction
with
Eq.
which
now
we of
thereby
variables.
identifies
~ and
s is,
and c o m p e l l i n g nature,
among the m o s t
proceeds
the
be
according
independent
Yl, 9 9 9 ,Ym-2; (1.4.4),
if
of
to the
t:
As
this
were
following
deformation discussed not
so,
in the
THE SECOND LAW OF THERMODYNAMICS
differentials
of
85
these
particular
coordinates
appear on the right-hand side of Eq. AA/AC and AB/Ac are likewise
(1.13.3).
independent
for,
if
it
to
did,
[I].
quantities
to
[2] The ratios
depend on this set,
[3] ~c cannot depend on Yl,...,Ym-z;
then
hA
deformation coordinates
have
of these coordinates:
if this were not so, s c would necessarily in c o n t r a d i c t i o n
would
would
have
to
in the same manner
depend
on
these
in order for these
to cancel out from the ratio AA/Ac, as is necessary
for consistency with [2] and [I] . But h A cannot possibly depend on the deformation coordinates initial assertion. the deformation
of system B, thus v e r i f y i n g the
By similar reasoning,
coordinates
xl,...,xn_ 2.
Ac cannot depend on [4] h A cannot
depend
on xl,...,xn_ 2 and AB cannot depend on Yl,...,Ym-2; for, according to [3], these x i and Yl are not functionally must
therefore
[2].
However,
quantity
be missing is
common
functions hA, ~B, and and
(SA,SB,t),
of assertions to
in
[5]
[I ] - [4] .
AA/AC and AB/Ac. would
have
hA-
4A(SA)T(t);
B,
and
C.
[5]
The
three
this is an elementary consequence
the
form
4A(sA)T(t),
in which T(t)
temperature
t which
4B(SB)T(t),
and
is a common function
cancels
from the ratios
If this were not so, the ratios AA/A c and AB/AC
necessarily
finally follows
A,
to the
[6 ] The functional dependences referred
respectively,
of the empirical
to
to satisfy
does not apply
~c are at most functions of (sA,t) , (sB,t)
respectively;
must
4C(SA,SB)T(t)
from h A and AB in order
this chain of arguments
t which
involved in Ac and
depend
on t,
in c o n t r a v e n t i o n
to
[2].
It
that
AB -- 4B(sB)T(t);
Ac - 4c(SA,SB)T(t)
(1.13.4)
and
~QA-
T(t)~A(SA)dSA;
~QB-
T(t)~B(SB)dSB;
~Qc- T(t)~c(sA,SB)dscIt turns that
out
function
convenient for which
to define dS(s)
(1.13.5) the metrical
= ~(s)ds;
then,
entropy
S as
provided
only
8~
I. FUNDAMENTALS
that
~(s)
is
integrable
so
that
S = f~(s)ds
is defined,
one
obtains
~QA = T(t)dSA
~Qn = T(t)dSn
(1.13.6)
~O~ = T(t)dSc,
where dSc(SA,SB) m ~c(Sa,Sn)dsc(Sa,Sn) " Inasmuch temperature
scale
regardless study,
as
of
it
is
function
T
specific
called and
the
may
properties
absolute
be
used
of
of
an
denominator the
temperature
as
empirical of ~Q,
system
under
(functlon)
a universal
in
function
for
temperature.
Note (1.13.1)
same
serves as an integrating
the
thermodynamics measuring
the
finally
that
the
substitution
leads to the additivity
of
(1.13.6)
relation
(1.13.7)
dS c = d S a + dS B.
It follows
that S c = SA + Sn, where we have
constant of integration Notice restricted
into
that
to zero.
in
ourselves
set the a r b i t r a r y
the to
foregoing reversible
we
have
necessarily
processes.
For,
an
irreversible process cannot be c h a r a c t e r i z e d by a small number of
deformation
coordinates
(see
Section
I.I).
To
emphasize
this feature we therefore write
~Q[rev
(1.13.8)
= TdS.
It should also be noted that a reversible necessarily as well. process
i sentropic" The
If ~ Q l r e v -
question whether
is to be considered
Q-
adiabatic process
0 then n e c e s s a r i l y 0 implies
in Exercise
is
dS = 0
AS = 0 for
any
1.13.1.
One additional feature of the Second Law must be taken up at this point, which relates a
finite,
possibly
isolated system.
to the entropy change incurred in
irreversible
process
in
an
adiabatically
Consider such a system in an initial state ~I
c h a r a c t e r i z e d by the set of d e f o r m a t i o n variables x I and entropy S I and
its
transition t o
a final
state
~2 a s s o c i a t e d
with
x2
87
THE SECOND LAW OF THERMODYNAMICS
and S2; the possible
achievable values
for S 2 cover some range
R, such that if ~,(x2,Sa) and ~b(X2,Sb) are two states accessible from
~I,
then
so
are
between S, and Sb. entropy for
all
states
Further,
~2(x2,$2)
for
which
S 2 lies
S I must lle in R, since this is the
every final state that is reached from ~l(xl,sl) in
any adiabatic
quasl-statlc
process.
that S I must be on an end point
It is important
to note
in R; if this were not so then
the final state ~2(x2,$2) would involve an entropy S 2 which can have
any
value
changing
the
sufficiently
deformation
close
ways
without
processes
it
neighborhood Principle.
altering
is
then
of
~i;
S I.
coordinates
adlabat~c quasi-static processes, of
to
this
subsequently
through
a
variety
of
one can adjust x in a variety
S 2.
Through
possible
By
to
flatly
this
reach
combination
every
contradicts
state
in
of the
Carath~odory's
The only way to avoid such an impasse
it to demand
that S 1 form an end point of R; then either S 2 _> S I or S 2 >_ SI, independent
of what the initial state might be.
Having once settled on one of the two alternatives, cannot
switch
to
situation held,
the
other"
For,
suppose
so that for any adiabatically
the
one
contrary
isolated system
all states ~ accessible from an initial configuration ~i had an entropy S >_ S I.
Suppose further,
that for any such system all
states ~ accessible from an initial state ~2 had an entropy such that
S _< S 2.
Then
for
a particular
state
for
which
corresponding
entropy happens
< $I, neither
the state ~I nor the state ~2 is accessible
~.
to satisfy
~
This then means, however,
the condition
that ~ is accessible
the
S2 < S from
from both ~I
and ~2; otherwise we would contradict the requirement that S be intermediate system. states
between
of
both
accessible, Principle. the
again
S 2 in the
~Q[=,vthat
larger in
and
adiabatically
clear
smaller
of
the
the choice. TdS; dS
inequality The
by universal _> 0,
so
that
convention
of
isolated
and
would
the
one must
once
selection
an
entropy
violation
To avoid contradictions
direction
abide by
and
S 1 and
That is to say that from the initial configuration
Carath~odory
therefore
for
is based
all,
in Q
choose
and
then
on the relation
one requires
increase
become
in a
that T >_ 0 reversible
~8
I. FUNDAMENTALS
process S.
involving heat exchange
This
now
leads
is matched with an increase
to a new corollary
to the
second
in
law for
processes which do not involve heat exchange between the system and the surroundings: The
entropy
of
the
final
carried out adiabatically
state
for
is never
any
process
less than that
of the initial state.
Herein, property
then,
one
of the entropy
can
detect
function"
a very
important
It provides
useful
an indication
whether or not a contemplated process can proceed spontaneously in an adiabatically process
or
totally
isolated
to occur it is necessary
system.
For
such
a
that the entropy of the final
state of the system be greater than that of the initial state. If
the
reverse
operates
situation
in the opposite
Thus,
for
any
isolated system,
holds,
the
process
under
sense.
process
dS >_ 0
whatsoever
in
an
adiabatically
and AS _> 0.
Implicit in the foregoing are several features" events occur in a totally isolated system, of constraints such processes surroundings
study
(a) When
through the removal
(for example, by unlocking a sliding partition), remain unaffected
by any manipulations
and are therefore uncontrollable
in the
and spontaneous.
The entropy of a spontaneous process in such an isolated system must
always
course
and
~eached an
the
has
system
the
process
set
its maximum value.
in.
a
decreases
for
conditions
where in
a
such
situation system the
has At
run
that
its
natural
point,
S has
(b) For any process whatsoever
equality
is carried out reversibly
encounter
However,
until
equilibrium
isolated
process can
increase
in in
system
dS
-
holds
only
if
and adiabatically. which
the
processes
interacts
circumstances
0
one
carried
with
must
entropy
its
in the
(c) One actually out
under
surroundings.
encounter
somewhere
else in the universe a compensating process such that the total entropy change of the system and that of all its surroundings where compensating processes
occur is always nonnegative.
THE SECOND LAW OF THERMODYNAMICS
We
further
pressure-volume carried
note work
that is
dE - ~Q - ~W - TdS
represents
developments,
special
and
case
where
one may combine
where
all
only
changes
the First
are
and Second
into the form
(1.13.9)
- PdV.
the
starting
one must note
the energy and the entropy, stressed
the
point
for
all
subsequent
beginning with Section I. 17.
Finally,
As
for
involved
out reversibly,
Law of Thermodynamics
This
89
earlier,
the
an important
difference
between
considered as a function of state. energy
of
a system
can be
altered
solely by transfer of heat or work or (as shown later) matter across
the boundaries.
By contrast,
the entropy
can also be
changed by processes occurring totally within the system. as
the
performance
adiabatically
can
system,
so the
can
used
be
instance
one
be
of used
transfer
to
track
must
be
work to
(reversibly track
of heat the
to
change. avoid
or
energy
reversibly
entropy
careful
the
Just
otherwise) change
of
a
across boundaries In
changes
this that
latter occur
totally within the system in order to keep an accurate account 9of entropy changes.
EXERCISES
1.13.1 Is it correct to state that for any process for which Q 0, one must have AS - 0 as well? If there exist exceptions, can you classify such cases? 1.13.2 Prove that the postulate rendering AS > 0 for any spontaneous process in isolated systems is consistent with making the universal temperature function T positive. 1.13.3 Various recourses to experiment have been proposed to settle the question whether AS increases or decreases in the course of an irreversible process. (a) Consider an adiabatic change in internal energy produced by frictional effects. In which direction does the energy change? What can you then conclude about AS? (b) Consider the adiabatic change in pressure and temperature of an isolated gas when its volume is changed irreversibly. How does AS change in
90
I. FUNDAMENTALS
this process? (c) Give reasons why this approach is considered to be relatively 'inelegant' as compared to the discussion in the text. 1.13.4 An adiabatic enclosure is filled with supercooled water and allowed to stand. After a while some ice is observed to form. Obviously, the process is spontaneous, yet it appears that there is an increase in order, hence, a reduction in entropy. Can you think of a way that gets you around this apparent violation of the Second Law? 1.13.5 A supersaturated salt solution is placed in an adiabatic enclosure. After a while a very small amount of salt precipitates out. One would argue that the separation of a single phase into two would result in a system that is less 'mixed up' at the end than at the beginning. This seems to violate the Second Law. Provide a concise argument which circumvents the conceptual difficulties by writing out an expression for AH and for AS accompanying the precipitation of An moles of salt and the concomitant change AT in temperature. 1.13.6 Is an adiabatic process necessarily reversible? Is a reversible process for which dS - 0 at every stage necessarily adiabatic ?
I. 14
AN ENTROPY ANALOGY
As was
the case
that
for the First Law,
illuminates
the
follow
the
change
is to be likened
two
example
Second
points
mountain
A
and
climber
provided
B,
Law by
one may provide
of Thermodynamics. Spalding
and
to a difference
ASAB, on
undertakes
a parable
rough
Cole 7.
ASAB
in
we
Entropy
in elevation
mountainous
to measure
Here
between
terrain. terms
of
A the
number of steps nf, each one-foot in height, which he must take to get from level A to level B. a circuitous elects
to
route
take
along
a direct
a firm path, route
which is full of dirt and gravel, step. than
Now the increase the number
taken:
If the climber elects to take
along
then ASAB -- nf. a
steep,
slippery
path
then slippage occurs at every
in altitude of the mountaineer
of one-foot
If he
incremental
The climber can now only establish
steps,
nl,
is less
that were
the inequality ASAB
7D.B. Spalding and E.H. Cole, EnEineering Thermodynamics (Arnold, London, and McGraw-Hill, New-York, 1959).
91
CYCLIC PROCESSES
< n e. Considerable
work has been wasted
in the
form of heat
supplied irreversibly to the countryside when the climber, dirt and gravel
resettles
yet another
method
at every step.
Obviously,
of establishing
AS~
there exists
namely by consulting
geodetic survey maps on which altitude contours are entered. It should be clear change, that
that ASAB corresponds
to an entropy
that n~ and n, simulate J~Q=/T and J~QI/T respectively,
the
firm
irreversible
and
loose
processes,
paths
correspond
to
and that contour
reversible
and
on a map
are
lines
analogous to tabulations of entropy values.
The shortcomings
of the parable should be explored by the reader.
1.15
CYCLIC PROCESSES IN RELATION TO REVERSIBILITY AND IRREVERSIBILITY.
CARNOT EFFICIENCY
(a) The considerations powerful tool in Consider
two
of cyclic processes
final deductions
points
in
based on the
configuration
infinitesimally close to one another, 2 in Fig.
1.15.1.
constitute
Choose
Second Law.
space
which
as represented
a particular
a very
quasistatic
are
by i and process
which takes a given system from state I to state 2; during this step let the heat exchange between system and surroundings be given as ~Q~-2 (in Exercise 1.15.1 we deal with the question as to
whether
it
positive).
matters
if
this
quantity
is
negative
Select a second, irreversible path that effects the
same i~2 change and that involves a heat exchange ~Q~-2. that
this
latter
irreversible appropriate
path
process,
_
that
is
dotted
the path
on
lies
the
diagram:
outside
to quasistatic processes.
dEi-2 + ~I-2_..rand ~Q~-2
Note
or
functions of
energy
Being
the phase
an
space
By the First Law, ~Q~-Z
dE I"2 + _..~ , so that
(1.15.1)
_
the
Note
differentials
have
canceled
out;
state, they are the same for both processes.
being The
92
I. F U N D A M E N T A L S
2 \\ r
1
x2
FIGURE 1.15.1 lllustration of a reversible path (solid curve) connecting states I and 2, and of an irreversible path (dashed curve) connecting states 2 and i. The dashed curve is meant to convey the fact that the irreversible process involves many thermodynamic coordinates which fall outside the domain of the indicated configuration space.
differences
in Eq.
(1.15.1)
cannot vanish.
If they did
reversible and irreversible paths would have to coincide, ~Q and ~W depend on the chosen paths. contradiction of terms.
Thus,
This would
the algebraic
the
since
lead to a
sums in (1.15.1)
must be either positive or negative. Suppose
first ~Q~-2 _ ~Q~-2 m ~Q~-2 + ~Q~-Z > 0; then the
work involved in completing the cycle by going from I to 2 via path i and returning to I via path r is given by ~ - 2 ~-2
+ ~W~-Z > 0.
expended
That is to say"
(i.e., put into the system)
~Q~-I > 0 and have obtained
_ ~z-2_..=_
In executing a cycle we have an amount of heat ~Q~-2 +
from the system
(i.e.,
the system
has performed) an exactly equal amount of work ~W~ ~2 + ~2~z > 09 w.. r No other changes have occurred in the universe.
Suppose next that ~Q~-2 _ ~Q~-2 m ~Q~-2 + ~Q~-Z < 0, so that by Eq. (1.15.1) ~ ~ 2
_ ~-2
_ ~W~2 + ~ - i
< 0.
A similar line
of reasoning now shows that in going around the cycle once we
CYCLICPROCESSES
have
93
expended
(i.e. ,
put into the system)
an amount of work
~WiI"2 + ~W z'1 < 0 and we have obtained from the system (i.e., the system has
transferred
to its surroundings)
amount of heat ~Q~+2 + ~Q~*I < 0.
an exactly
equal
No other changes have occurred
in the universe. Which of these alternatives do we choose? Let us simplify ~fQr1".2 - TdS I~2 - TdS.
the notation by setting ~ Q ~ 2 One must now consider
, ~Qi and
the possibilities
(a) ~Qi - TdS > 0, i.e., TdS < ~IQi, or (b) ~IQi - TdS < 0, i.e., TdS
> ~Qi.
The
present
discussion
must
apply
to
all
cases
including the special situation where the irreversible process is carried out adiabatically.
Under alternative
obtains TdS > 0 for the adiabatically contradictions are uncovered. the
corollary
to the Second
isolated system,
Under alternative
require TdS < 0 for an irreversible, Law,
this possibility must be ruled out.
(b) one then (a) one would
adiabatic process,
discussed
and no and by
in Section
1.13,
We thus claim that (I.15.2a)
~Qi < TdS - ~Qr.
This result is eminently sensible:
If we take the system
from state I to state 2 by a reversible
sequence of steps the
entropy change must be matched by a heat transfer of magnitude dQrev/T.
If
the
same
change
is achieved
by
an
irreversible
operation,
part of the overall entropy change
is generated by
processes
totally
amount
required
to
within
match
the
correspondingly smaller.
the
system.
remaining Also,
The
entropy
change
of will
heat be
from (i.15.7a) we find
~W i < ~Wr,
(I.15.2b)
and for any finite changes
S2
- S1 >
Equation
(1.15.3)
~QI/T.
(1.15.3)
open the question
must as
be
used with
care,
for it leaves
to what temperature is to be employed in
~4
I. FUNDAMENTALS
conjunction with the irreversible process that takes the system from state (1.15.3)
I to state 2.
In later arguments we shall use Eq.
solely in situations
where
the system under study
thermally properly anchored to a reservoir; temperature
is
T then is the fixed
of the surroundings.
Consider
next
a different
taken from some state
process
wherein
through a macroscopic
a system
is
cycle back to the
same initial state by means of a reversible process.
Denoting
such a path by the integral sign ~, we then find that
(1.15.4)
~dS - ~IQr/T - 0. On
the
other
process,
~QI/T
hand,
(1.15.3)
shows
that
in
this
cyclic
for which S I - S 2,
< 0.
(1.15.5)
Both statements
~Q/T
Eq.
may be combined to read
~ 0,
(1.15.6)
which is known as the Clausius In
this
irreversible
connection
note
the
an
no
isolated
system.
direction
We emphasize a
means
adiabatically for which system;
occurs
in an
If an irreversible process proceeds at all,
in the spontaneous
as
that
to
of
there is
a process
return
nature
point without incurring other changes in the universe; influencing
can never
very
starting
of
one
again
the
way
process:
inequality.
of
once more that the state
monitoring
isolated
S decreases conversely,
that increases
whether
a
the entropy. function S serves
given
process
system is indeed possible. can occur
any process
it must go
in
an
No process
in an adiabatically for which S increases
isolated in such
a system will be spontaneous. For a system A which exchanges heat with surroundings
B
we consider an enlarged system in which the original system and all of
its surroundings
form a composite isolated system;
then
95
CYCL,C PROCESSES
dSto t -
dS A +
d S B >_ O.
(b) Consider useful
now the operation
as a continuous
source
being o p e r a t e d in cycles,
of a heat engine.
of power
it must be
in the universe only. as
to
whether
engines
operate
temperatures that heat
All
In Exercise 1.15.2 the question is p o s e d made
next
apply
the
engine
T h and T c.
Let
between
The
two
to
noncyclic
reservoirs
do not appreciably
Qh be
the
heat
reservoirs are
alter
transfer
(Qh > 0 or Qh < 0 according
as heat
engine at the hot junction),
per
across
reservoir
the
so
at
large
the temperatures cycle
across
the
T h and the engine
into or out of the
and let Qc be the heat transfer per
boundary
at temperature
flows
kept
assumed
b o u n d a r y b e t w e e n the reservoir at temperature
flows
it started.
the operation of the engine thus occur
statements
transfers
each.
cycle
of
such as rockets.
We
of
the
capable
so that at the end of every cycle the
engine gets back to the same state from which net changes accompanying
To be
separating
the
engine
and
the
T= (Qc > 0 or Qc < 0 according as heat
into or out of the engine
at the cold junction).
If now Qh > Qc, or Qh - Qc > 0, then in the course
of one
cycle we must have W > 0 in order that the First Law applied to the
cyclic
process
arranging matters
(Qh - Qc)
- W-
so that heat
from the hot reservoir the cold reservoir,
0 may hold.
is transferred
and heat
That
is,
into the engine
is rejected from the engine
the difference
by
Qh " Qc is transformed
to
into
work W > 0 performed b_.y the engine. We now ask how efficiently this energy c o n v e r s i o n process can be carried
out.
The efficiency
is m e a s u r e d by a quantity
defined as i W o r k out/Heat
To
get
at
(1.15.6).
in .
this In
(1.15.7)
quantity
the
present
recall case
reduces
to a sum of processes
Qh from
the hot
reservoir
the
the
integration
occurring
into
the
Clausius
inequality in
during heat
engine
and
(1.15.6) transfers
- Q= from
the
~
I. FUNDAMENTALS
engine
into the cold reservoir.
Thus,
7.(i)Qi/Ti - Qh/Th - Qc/Tc _< 0,
(z.15.8)
Qh/Th --< Qc/Tc,
(1.15.9)
where
Qh,
Qc
are
both
positive
quantities,
inasmuch
as
a
negative sign precedes Qc whenever we consider the heat removed from the engine.
Hence
(1.15.9) may be rewritten as
(1.15.1o)
qo/qh >- T o/mh, or
-
Qc/Qh -
(YT) ~jaj. I. 18.9 (a) Show that the adiabatic and isothermal compresslbilitles ~s i - v-l(av/aP)s and ~T " - V-I(aV/aP)T are related by ~s i 7-I~T, where 7 i Cp/Cv. (b) Prove that ~s - ~T -- (T/CpV)(aV/aT)~. (c) Prove that for an elastic system C= - Ce ,
,
~,&
,
-
-
'IV
,,
.
j~,~
.
.
,
.
.
.
.
.
~,Bial.
1_18.10 Show that for any material whose equation of state is specified according to P - P(T,V) the following equation is obeyed: Pap - ~av, wherein ap - P-l(aP/aT)v, av i v-1(aV/aT)p and ~ - - v(aP/aV) T. 1.18.11 Show that for any material that is representable by an equation of state of the form P f(V).T the energy is independent of the volume, so long as the function f(V) depends on V alone. 1.18.12 (a) Prove that (aS/aP)B > 0 and (as/av) E < o, by noting that V, P, T are all positive. (b) Prove that (as/av)p CpTVa, where ~ - V-l(aV/aT)p. Is (as/av)p always positive or always negative ? 1.18.13 Relate the quantity (aV/aT) s to quantities that may be experimentally determined. (b) From the Gibbs equation TdS - dE + PdV prove that for all adiabatic processes (aT/aP)s - (T/Cp) (8V/aT)p. 1.18.14 For a van der Waals gas determine the Joule Thomson coefficient and inversion temperature T i in terms of a, b, P, T, and Cp. Make a sketch of T i versus T; note and comment on the double-valued nature of the function. 1.18.15 Let the force constant of a spring depend on temperature as k cT with c > 0, where c depends only on length L. (a) Show that E is a function of T only and that S decreases with increasing length. (b) Show that T rises if the string is stretched adiabatically. (c) For a spring which follows Hooke's Law the element of work a'Wr is kdx, where dx is the incremental elongation and where the spring "constant" k is p a r a m e t r i c a l l y dependent on temperature. Find the energy, heat capacity Cx, entropy, and Helmholtz free energy for this system. -
131
FUNCTIONS OF STATE
1.18.16 The equation of state of a spring is given by T (a - bT) ( L - Lo(T)), and the increment of work is given by a~w= - ~dL. Here I" is the tension, L the length, L 0 the extension of the spring under zero tension, a, b are constants, T is the temperature. (a) Determine AG, AH, AS, and AE for a process in which the spring is extended reversibly to a length 2L 0 at constant T and P. Assuming d V - 0, express your results in terms of = ~ IZ1(dL0/dT), a, b, T, and L 0. (b) Determine Q=,v for the process of stretching. Assuming A V - 0, determine W=,v for the process of stretching. (c) Let the spring snap back to its original position. Now calculate AS and AE, and the entropy change in the surroundings during this latter process. What is the overall entropy change in the system and surroundings during the cycle just described? Hint" Use Maxwell's relations to obtain a partial derivative involving S and L. 1.18.17 (a) Determine expressions for Cv, E, S, F, and G for a van der Waals gas. (b) Show that for an adiabatic change T(V - b) 7-I and (P + a/V 2) (V - b) 7 are constants. 1.18.18 (a) Determine (8E/SV)~ and (8H/aP)~ for a gas obeying the van der Waals equation of state. (b) Show how the entropy changes with pressure and with volume at constant temperature for the above type of gas. (c) Prove that C v is independent of V for this type of gas, provided the van der Waals "constants" are taken as independent of T. 1.18.19 A glass ampoule containing i mol of liquid water at 100~ is inside an evacuated container of volume V. The ampoule is broken, while the system is maintained at 1000~ Calculate AS for the change in state (a) for the case that V I0 liters, and (b) for the case that V - i00 liters. Make any reasonable approximations required. 1.18.20 The specific heat of CC14(2) for t < 25~ is 0.20 cal deg-Zg -I at a constant pressure of I atm. Find its specific heat at constant volume at 25~ at this temperature, the isothermal compressibility is given by (107.70 + 99.4 x 10-aP + 70 x 10-6p2)x 10 -6 bar -1, its density is 1.58455 g cm -3, and its coefficient of expansion is 0.00124 deg -1. 1.18.21 By how much does the enthalpy of 3 tool of Cl2(g) change when its temperature is increased at a constant pressure of I atm from 300 to 400 K? Its heat capacity at a constant pressure of i atm in this temperature range is 7. 5755 + 2.4244(I0-3)T 2 - 9.650 (10-7)T 4 cal deg -1 tool-I. 1.18.22 The Berthe!ot equation of state as applied to many gases reads -
PV - RT
i +
I - 6 128 P=r
-~-] ~ '
where T= and P= are the critical temperature and pressure.
132
I.
FUNDAMENTALS
Derive an equation showing how the enthalpy change for such a gas is related to a pressure change from P - PI to P - P21.18.23 (a) Determine the change in Cp for N 2 gas when the pressure is changed from 0.I to 400 atm at 270~ The van der Waals constants for this gas are a - 1.39 llter 2 atm/mol 2, b - 3.92 x 10 -2 llter/mol. (b) Repeat the calculation for the change in C v. 1.18.24 Calculate the entropy change in irreversibly converting i mol of supercooled water at -10~ to ice. Hint" Calculate this quantity by determining the change in entropy involved in heating the water reversibly to 0~ freezing the water at 0~ and freezing the ice reversibly to -10~ Set o C~(2) - 18 cal/deg-mol, Cp(s) - 9 cal/deg-mol, Allo 2 7 s - -1436 cal/mol. The solid or liquid is maintained at a pressure of I atm throughout. For liquid water (@V/aT)p = 0.015 cm3/deg. Calculate the change in entropy when the pressure over the liquid is reduced by 1/2 atm. Check your sign carefully. 1.18.25 The accompanying Table (Table 1.18.1) provides a listing of the Joule-Thomson coefficients for N2, ~j (aT/aP)H , over a large range of T and P. "
Table 1.18.1
Joule-Thompson
Temperature
Coefficient
for Nitrogen in deg arm -I Pressures (atm)
I
20
60
I00
200
200~
0.0540
0.0460
0.0365
0.0260
0.0075
I00
0. 125
0. 114
0.0955
0.0760
0. 0415
50
0. 179
0. 166
0. 141
0. 115
0. 066
25
0. 214
0. 200
0. 169
0. 138
0. 078
0
0. 257
0. 242
0. 204
0. 166
0.090
-50
0. 384
0. 362
0. 299
0. 231
0.094
-i00
0. 628
0. 578
0.443
0. 281
0.062
(a) Through self-consistent procedures determine the final temperature achieved by the throttled expansion of N 2 gas initially at 25~ from 200 to i atm. (b) Express the Joule-Thomson coefficient for as gas subject to the approximate
ILLUSTRATIVE EXAMPLE: J O U L E - T H O M S O N
133
COEFFICIENT
equation of state PV - RT + B(T)P, where B is the so-called second virial coefficient. (c) Using (b) and the accompanying graph (Fig. 1.18.2) for CO 2 determine the approximate temperature at which Nj changes sign. (d) Calculate the Joule-Thomson coefficient for CO 2 at 125~ (e) Derive an expression for (8Cp/aP)~ in terms of the Joule-Thomson coefficient of the gas. (f) Is it not it a self-contradiction to compute (8Cp/aP)T when C e implies a heat capacity measured at constant pressure? Why then do we not set ( a c e / a P ) T - 07 Explain these matters carefully. (g) for N 2 gas C p - 6.45 + 1.41 x 10-aT - 0.81 x 10-7T 2 cal/deg-mol. Using Table 1.18.1, estimate (8Ce/aP) T for N 2 at 300 K, and estimate the change in heat capacity with a pressure change from I to i01 atm.
Temperature 200~
20
1 CO2
l
~
Pressure 60 0. 0365
i 0. 0540
20 0. 0460
i00 0. 0260
200 arm 0. 0075
i00
0.125
0.114
0.0955
0.0760
0.0415
50
0. 179
0. 166
0. 141
0. 115
0.066
,
I0 0
25
0. 214
0. 200
0. 169
0. 138
0. 078
-10
0
O. 257
0. 242
0. 204
0. 166
0. 090
~ -20 U 0'~- :30
-50
0. 384
0. 362
0. 299
0. 231
0. 094
-i00
0. 628
0. 578
O. 443
0. 281
0. 062
-150
1.225
1.097
0.062
0.0215
-0.0255
-50 -60 / ! -
70
-8(300 400
5~)0 6(~0 700 T (K)
8~) 900
FIGURE 1.18.2
1.18.26 The standard entropy of Ar(g) as a function of temperature is given by S ~ (eu tool-I) - 8 . 6 8 + 11.44 log T. Find the change in Gibbs free energy for I mole of Ar(g) when its temperature is changed from 298 K to 348 K at a constant pressure of i atm.
I.A
ILLUSTRATIVE
EXAMPLE"
DEDUCTIONS
BASED
ON
THE
JOULE-
THOMSON COEFFICIENT (a) We illustrate the power of the general thermodynamic approach by examining a set of deductions based on the use of the Thomson coefficient.
We begin with Eq. (1.18.35b), which
134
, FUNDAMENTALS
we rewrite
as
(SH/aP)~--
~jCp.
(I.A.I)
From dH - TdS + VdP, (l.18.10b),
(SH/SP)~-
Next,
with
the M a x w e l l
relation
we obtain
-
T(SV/ST)p
substitute
(I.A.2).
in c o n j u n c t i o n
the
+ V-
-
equation
r/jCp. of
(I.A.2)
state
for
V
-
As an example we adopt the van der Waals
V(P,T)
in
equation
of
state" P - nRT/(V-nb)
Brute
force
dlfflcult;
inversion
RT/P
In
first
fourth V-
of
accordingly,
both sides by
V-
(I.A.3)
- an2/V 2.
the
to
solve
for
we resort to approximations.
V(P,T)
is
Multiply
(V - nb)/P: (I.A.4)
- a/PV + b + ab/PV 2.
approximation
replace
terms on the right,
RT/P
above
V
by
RT/P
in
the
second
and
to obtain
(I.A.5)
- a/RT + b + abP/R2T 2.
Then (aV/ST)p-
Solve Eq.
R/P + a/RT 2 - 2abP/R2T 3.
(I.A.6)
(I.A.I) for R/P and insert the result into (I.A.6)
to
find (8V/aT)p-
When
(V-b)/T + 2a/RT 2 - 3abP/R2T 3.
(I.A.7)
and (I.A.5)
are p l a c e d
in (I.A.2)
(I.A.7)
one finds
ILLUSTRATIVEEXAMPLE:JOULE-THOMSON COEFFICIENT
J3 5
112a 3P1 1(2a ) ~-~ - b - RZTZ ] = -~p ~-~ - b ,
(1.A.8)
~j - -~p
where we have neglected
the higher
order
term
in P/T 2 on the
right. Note
that
~j is positive
for
'large'
a and
'small'
b,
corresponding to large interatomic attractive forces and small interatomlc decreasing
repulsive P across
the temperature, of the gas. prevails, (I.A.8)
For
the porous
which
~j
>
0,
plug of Fig.
(aT/aP) H >
1.18.1
0:
decreases
is the effect we need for c o n d e n s a t i o n
For 'small' a and 'large' b the opposite situation
which
Generally,
forces.
is of no
interest
as the gas pressure
causes
negative.
~j
to
Further,
is increased
decrease, at
for possible
pass
'low'
the third term in
through
pressure
applications.
zero,
and
~j increases
as
turn T
is
diminished (Cp also decreases with T); higher pressures are then needed to effect a sign reversal in ~j. a change b(T)
Thus, one anticipates
in sign in ~j as P and T are altered and as a(T)
are changed by selection
of different
types
and
of nonideal
gases. (b) These matters determining ~j-
0.
The
satisfies
are addressed
the so-called central
inversion
term
in
more
quantitatively
temperature,
Eq.
(I.A.8)
vanishes
when
curve
of T i versus pertains
experiment. critical
the
left
to
One
value
temperatures equation.
Ti
the quadratic equation
(I.A.9)
T~ - (2a/Rb)T i + 3aP/R z - 0. A plot
by
Ti, at which
P is shown N2
sees Pc
(=
in Fig.
gas
and
that
at
is
300
atm)
a
in
given there
I.A.I; fair
the
agreement
pressure exist
that are derived from solutions
indicated with
Po b e l o w
two
a
inversion
of the quadratic
To achieve liquefaction of the gas one must stay to of the curve
larger this quantity,
in Fig.
I.A.I,
for which
the more effective
the gas through the porous plug.
Wj > 0.
the pressure
According to Eq.
The
drop of
(I.A.8) one
136
I. FUNDAMENTALS
500~
"~.~
._. 400~ ~r,...)
o
"~, "x
~ 300"
"x x\
~
",,
.o= lOO~ >
,
~=
/
oOJ-
/////
o
--I00
20
FIGURE I.A.I
should large
100
200 Pressure
Joule-Thomson
therefore and b
60
is
select small,
300 Atan.
inversion curve for nitrogen.
a van
der Waals
and Cp is as
small
gas
for which
as possible.
should also operate at the lowest temperatures, the operating Fig.
pressure,
while
a
is One
consistent with
remaining within
the limits
of
I.A.I. (c) Another quantity of interest is the set of isenthalps
that
may
be
constructed.
Begin
with
dH
-
(8H/aT)pdT
+
(8H/aP)TdP and write dH - Cp(T, P) dT
-
CprIJdP 2a
-
Cp(T,P)dT
+
- ~-~ +
3abP RZTZ
+ b] dP,
(I.A. i0)
ILLUSTRATIVE EXAMPLE: JOULE-THOMSON COEFFICIENT
where
the
gases,
second dH
derivatives
l a__~C1 ~ 'apl T
is
an
refers
exact
specifically
dlfferentlal;
to van hence,
der
Waals
the
cross
must match:
2a ~
llne
[ ,3"I
6abP
(I.A.II)
- ~ .
Next, carry out an indefinite integration over pressure on both sides at constant T:
cp
2aP (3ab ~ p2 - ~ - k-z~ l + C(T),
(I.A.12)
where C(T) is an arbitrary function of temperature. (I.A.12) i r/j - - ~
Then, from
and (I.A.10) (8H) 2 a / R T - 3abP/R2TZ - b ~ T - C(T) + (2a/Rr z)P - (3ab/RZT ~)Pz
2a/RT - b = C(T) + (2a/RTZ)P '
(I.A.13)
where we have neglected higher order terms in abpn/R2T m. Consider next a process taken
from an initial
state
in which a van der Waals T1,P 1 to a final
state
convenient sequence of steps involves the following:
gas is
T2,P 2.
A
(i) Cool
the gas reversibly from T I to T2, keeping the pressure fixed at P1.
(ii) Expand the gas reversibly from P1 to P2 while holding
the
temperature
isenthalplc
at
T z.
conditions
In we
executing
find,
on
use
these
steps
of
(I.A.12)
under and
(Z.A.Z0), 0 - All - [ T2 CpdT T1
-r ~~
[
"
I
P1 + /P1 dH T2 - 3abP
+
2a 3abP ] RT 2 + R ~ 2 + b dP.
]dT
(I.A.14)
138
FUNDAMENTALS
I.
On adopting as
the approximations
sensibly
constants,
mm
H
mm
.
independent
of
already mentioned, T,
and
taking
a
regarding
and
b
to
C be
we find 2aPt [ i R
. I
+ C(T2"
TI) + -
~2
+ b
(P2 " PI),
(I.A. 15) or
GT I + bP 1 - (2a/R)(P1/TI)
= CT 2 + bP 2 - (2a/R)(P2/T2) (I.A.16)
- H(T1,PI) - H(T2,P 2) m H, a constant.
The
quantity
- H(T,P)
m
(2a/R)(P/T)
- bP
- CT,
which
is
a
constant under the c o n t e m p l a t e d conditions and approximations, fs the desired
P
-
isenthalp.
We see that the e x p r e s s i o n
[ "
RT
2a
-
"
provides us with a family of curves P -
P(T;a,b,C,H)
"
such that
for a given TI,PI,C and for a given gas with specific a and b we arrive
at
a
specific
value
of
H,
as
determined
from
Eq.
(I.A.17). Figure set of values
I.A.2 shows a schematic of HI,...,H 8.
point represents values. curves Fig.
The
T for a
The shape of these curves
for any
the value ~j for that specific
dashed
HI,...,H8; I.A.I.
plot of P versus
llne
this In
passes
through
schematically
numerical
work
regions
applications,
accurate
applications. proceed
llke
maxima
of
the
curve
one
should
(I.A.16),
Fig.
I.A.2
the of
recall
the
(I.A.17).
As
indicate
of T and P for which a given gas provides
possible Wj. more
plots
the
duplicates
approximations used in arriving at Eqs. concerns
set of T and P
the
the largest
With more realistic equations of state one can get plots The
that
serve
present
in such cases.
as
guidelines
discussion
shows
in e n g i n e e r i n g how
one
would
I 39
HEAT, CALORIMETRY, AND THERMOCHEMISTRY
HB ~
~H7
\\
H5
T
\ \\1~--------
/-/4
////
H3
////
H2 H1
~
0
FIGURE I.A.2
I. 19
HEAT, (a)
Schematic
diagram for isenthalps.
CALORIMETRY, Up
etherlal
P
to
now
quantity,
AND THERMOCHEMISTRY
heat
having
has
been
been
treated
introduced
as
deficit function which covered the difference, between AE and - W. with
a physically
both
a
set
of
We now complement
more
units
meaningful
and
a method
somewhat as
a
in any process,
these earlier concepts
discussion, for
a
originally
by
metering
introducing out
and
for
monltoring heats. The heat developed in a circuit by an electric current of I - I ampere flowing through a resistance of R. ~ I ohm (across a potential is defined
difference
of V , -
to be i joule.
i volt)
One calorie
for a time t -
i second
is defined as equal
to
4.1840 joules and corresponds very closely to the heat required to raise 15.5~ a circuit
the
temperature
More generally, is specified by
of
I g of pure
water
from
14.5
to
the heat developed by current flow in
140
, FUNDAMENTALS
(1.19.1)
Q I ~12R.dt I ;V.ldt.
(b) A convenient method for measuring heat flux utilizes calorimetry. derives internal
The
thermodynamic
from the First Law: energy
E I
for
has
the
likewise,
differential
(aS/aV)TdV.
procedure form
dE
I
the entropy S considered as
a function of T and V has the differential dT +
this
We saw in Section 1.18 that the
E(S,V)
(aE/aS)vdS + (aE/aV)sdV;
basis
(aS/aT)v
form dS =
If this latter relation is substituted
into
dE, one finds
(aE/aS)v (aS/aT)v dT + [(aE/aS)v (as/av)T + (aE/aV)s]dV.
dE =
(i.19.2a) Using the
the chain rule of differentiation
right,
and
Eqs.
(1.4.7),
in the first
(1.18.25),
(l.18.10a)
term on in
the
second, yields
dE I
(aE/aT)vdT + (aE/aV)TdV ,
(i.19.2b)
which shows that E may also be considered an implicit function of T and V.
However, as is to be shown in Exercise 1.19.1, Eq.
(i. 19.2b) is incomplete, though it remains extremely useful for our further development. At fixed volume and in the absence of other work dE I ~Q
i (aE/aT)vdT; thus, on introducing the definition for Cv, Eq. (1.18.12), we find
dE - ~Q = CvdT
(1.19.3a)
(V constant).
For finite processes
in which the temperature
is changed from
TI to T 2:
CvdT - AT wherein
the
average
defined by < C v > i
heat
(V constant), capacity
at
(i.19.3b) constant
volume
~ T2 TI CvdT /~~T~ dT, and where AT m T 2 - TI.
is
14 I
HEAT, CALORIMETRY, AND THERMOCHEMISTRY
Equation
(1.19.3)
adiabatically monitored
isolated
through
its
Adiabatlclty
is
surroundings
while
process
may
shows
be
system
the heat
at
to
volume
rise
prevent
is being
conveniently
transfer
constant
temperature
essential AT
that
if
heat
monitored.
executed
by
into an may
is
leakage The
be
known. to
the
calibration
supplying
a known,
small amount of electrical energy Q . - Jl2R, dt to the system and measuring
the
small
resultant
ATe;
this
establishes
and
permits Eq. (I.19.3b) to be used to determine Q for any process of interest.
Naturally,
calibration indicated
by
numerous flows, on
and
operation
the
other
the correct experimental procedures of are
superficial
techniques
much
discussion.
for measuring
as indicated by reference
calorimetry.
The
more
main
complicated Also,
than
there
and quantifying
are heat
to any of the numerous books
point
of
discussion
here
is
to
demonstrate at least one method by which Q can be measured. Analogous is held
remarks apply when the pressure of the system
fixed.
In
Exercise
1.19.2
the
reader
is
asked
to
establish that dH-
KQ -
CpdT
(P constant)
(I.19.4a)
and AH-Q-~
2 CpdT - AT
(I.19.4b)
(P constant).
1
The remarks of the previous paragraph also apply to the present case, except that P rather than V is held fixed. (c) In chemical thermodynamics the preceding concepts are largely
applied
One widely
to measure
used procedure
the heats
of
is to carry
very rapidly and adiabatically
chemical
out
reactions.
a combustion
in a bomb calorimeter,
step
thereby
changing the system from the state T - T o , P - P0, and V = V 0 to the
state
T - TI,
P - P2,
and V = V0;
in this
step
AE -
0
because no work has been performed and no heat flux has taken place
in the time scale of the first step.
The products
are
142
,
then slowly
cooled
so that
the
system ends up in the c o n f i g u r a t i o n T - To, P - Pi, V - V 0.
In
this step A E z z -
T
to their
initial
temperature,
FUNDAMENTALS
CvdT, where C v includes
c a l o r i m e t e r that chlanges in temperature. of state, AE - AEII. + A(PV).
the p o r t i o n of the
Since E is a f u n c t i o n
To convert to enthalples we write AH - AE
W h e n e v e r condensed phases are involved A(PV) tends to
be negligible,
but for reactions
of the a p p r o x i m a t i o n
A(PV)
involving gaseous species use
= RT An is generally
satisfactory,
where An is the increase in mole numbers of the gaseous species at the average is
asked
to
temperature,
carry
out
T.
In Exercise
corresponding
1.19.3
analyses
the reader
for
reactions
carried out at constant pressure. The foregoing m e t h o d o l o g y applies, of
process,
particular, standard
including
to cases where
conditions,
one atmosphere quantities
equilibration
i.e.,
the
reaction
with
at the temperature
all
zero,
e.g.,
to any type
procedures, is carried
species
and,
in
out under
at a pressure
of interest.
obtained for these conditions
by a s u p e r s c r i p t
of course,
of
Thermodynamic
are usually indicated
E ~ 9 C o 9 S o 9 and the like
EXERCISES
1.19.1 Provide a thoroughgoing d i s c u s s i o n to show in what sense the differential equation dE (8E/aS)vdS + (8E/aV)sdV is more fundamental than the relation d E - (8E/aT)vdT + (8E/aV)TdV. 1.19.2 Provide a d e r i v a t i o n of Eq. (1.19.4). 1.19.3 Discuss the basic calorimetric method for d e t e r m i n i n g AH for a reaction carried out at constant pressure. 1.19.4 For a fluid any two of the three variables P, V, t (empirical temperature) are independent. An increment of heat may now be described in several alternative ways ~ Q - Cvdt + LvdV - Cpdt + LpdP - MvdV + MpdP. (a) Express in words the m e a n i n g of the various C, L, M coefficients. (b) Derive expressions for Mv(Lv,Cp, Cv), Mp(Lp,Cv,Cp) and show that Mv/L v + M p / L p - I. (c) Derive expressions for (@P/at)v and (@V/at)p in terms of Cp, Cv, Lp, or L v. 1.19.5 The value of AH for the formation of FeS from its elements at 25~ is -22.72 kcal/mol. Determine AE per mol for the process at i atm. The densities of Fe, S, and FeS are 7.86 x 103 , 2.07 x 103 , and 4.74 x 103 kg/m 3 respectively. 1.19.6 One hundred grams of lead at IO0~ are put in 200
HEAT, CALORIMETRY,AND THERMOCHEMISTRY
143
g of water at 20~ the resulting temperature at equilibrium is 21.22~ Calculate the specific heat of lead. 1.19.7 Consider a system surrounded by a heat reservoir, both of which are in an adiabatic enclosure. The system can exchange work with surroundings outside the enclosure. (a) Suppose the system is taken from state A to state B. Express the entropy change of the system in terms of Q, AEAB , W and do the same for the bath. What is the overall change in entropy? (b) Allow the system to return spontaneously to state A without any work being done. Express ASBA and AEBA in terms of the entropy and energy change for the inverse process. Explain how any energy is dissipated in the process. On this basis obtain AS for the reservoir, and the overall entropy change for the process B ~ A. (c) Show how the above may be applied to determine the entropy change of a freely dropping object of mass m. (d) Repeat, for a spring whose equation of state is - ~ ( L - L0) where T is the tension, L the length, ~ the force constant, and L 0 the length at zero tension. Assume that when completely extended, Lf - 2L0, and that the stretching is accomplished isothermally. 1.19.8 Calculate the changes in the entropy of the univers~ as a result of the following processes" (a) A copper block of mass 400 g and thermal capacity 150 J deg -i at IO00~ is placed in a lake at 10~ (b) The same block at 10~ is dropped from a height of i00 m into the lake. (c) Two similar blocks at 100~ and 10~ are joined together. (d) A capacitor of capacitance I ~F is connected to a 100-volt battery at 0~ (e) The same capacitor, after being charged to i00 V is discharged through a resistor at 0~ (f) One mole of a gas at 0~ is expanded reversibly and isothermally to twice its initial volume. (g) One mole of gas at 0~ is expanded irreversibly and adiabatically to twice its initial volume. 1.19.9 Consider two identical springs, one at length L 0 (and, therefore, not under tension), and the other at length 3L 0. If these two springs are dissolved in aqueous acid solution at temperature t, will there be any difference in the heats of solution for the two springs, and if so, by how much will these heats differ? 1.19.10 One gram of zinc is placed in excess dilute H2SO 4 at 15~ contained in a cylinder fitted with a weightless, frictionless piston of cross-sectional area 490 cm 2. As the reaction proceeds the piston moves outward against the external pressure of I atm. The liberated heat of reaction is allowed to dissipate and eventually the temperature of 25~ is restored. The total amount of heat lost by the reaction mixture during this time is found to be 36.43 kcal, and the piston has moved outward a distance of 50 cm. Find AE for the contents of the cylinder.
144
, FUNDAMENTALS
1.19.11 Two identical bricks, one at 700 K and the other at 300 K, each weighing 2000 g, are placed in contact. Find ASbri=k,, if the heat capacity of brick is 0.20 cal deg-lg -I. 1.19.12 Two moles of an ideal monatomic gas at 37~ and I atm are compressed reversibly and adiabatically until the pressure is doubled. What final temperature is attained? Find W, Q, AE, and AH for this process. 1.19.13 (a) Three moles of an ideal gas (Cv - 4.97 cal deg-lmol -I) at I0.0 atm and 0~ are converted to 2.0 atm at 50~ Find AE and AH for this process. (b) Why cannot the value for W be calculated from these data? 1.19.14 If the change described in Exercise 1.19.13 is carried out in two stages, (a) a reversible adiabatic compression to 50~ and (b) a reversible isothermal expansion, find AE, AH, W, and Q for each stage and also for the overall process. Compare AE and AH with the answers to Exercise 1.19.13. 1.19.15 If the change described in Exercise 1.19.13 is carried out in two stages, (a) an adiabatic compression to 50~ using a constant external pressure of 18.1 atm, and (b) an isothermal expansion against a constant external pressure of 2.0 atm, find AE, AH, W, and Q for each stage and also for the overall process. Compare the overall values with those of Exercise 1.19.14. Why is Q ~ AH in (a), even though P.x was constant? 1.19.16 A certain gas obeys the equation of state P(V nb) - n R T and has a constant volume heat capacity, Cv, which is independent of temperature. The parameter b is a constant. For i mol, find W, AE, Q, and AH for the following processes" (a) Isothermal reversible expansion. (b) Isobaric reversible expansion. (c) Isochoric reversible process. (d) Adiabatic reversible expansion in terms of TI, Vl, V2, Cp, and Cv; subscripts of i and 2 denote initial and final states, respectively. (c) Adiabatic irreversible expansion against a constant external pressure P2, in terms of PI, P2, TI, and 7 ~
(cp/Cv). 1.19.17 Ten liters of nitrogen at 27~ are compressed reversibly and adiabatically to a volume of 2 liters. Calculate the final temperature" (a) with Cv - 4.95 cal/mol-deg; (b) with C v - 4.51 + 0.0010T cal/mol-deg. Assume that nitrogen is an ideal gas. 1.19.18 The heat combustion (AH) of tungsten carbide at 300 K is -285.65 kcal/mole WC, and the reaction is WC(s) + (5/2)Oz(g) - W O 3 ( s ) + CO2(g). Compute the heat for the same reaction if it takes place in a constant-volume bomb calorimeter at 300 K. Assume that the gases behave ideally and that corrections to standard states are negligible for solid species.
145
NUMERICAL CALCULATION OF ENTROPIES
1.19.19 In an adiabatic enclosure at 298 K 2.00 moles of CH4(g) are mixed with 5.00 moles of O2(g). A spark is produced in the mixture and the CH 4 is completely burned in the oxygen to CO 2 and H20. Assume ideal gas behavior and compute the final temperature of the gas mixture. What approximations are used in arriving at the final result? The following data are relevant: O2(g )" C ~ - 7.16 + 1.00 x 10-aT cal deg -I tool-I CO2(g )" C ~ - 10.57 + 2.10 x 10-aT H20(g)" C ~ - 7.30 + 2.46 x 10-aT CH 4"(g) C~ - 5.65 + Ii.44 x 10-aT
1.20
NUMERICAL CALCULATION OF ENTROPIES AND ENTHALPIES
(a) One the
of the
important problems
determination
experimental
of
heat
transition.
the
in thermodynamics
entropy
capacity
of
a
given
measurements
involves
substance
and
from
from
heats
of
Before considering this matter it is necessary to
examine the thermodynamic characterization of transitions. Suppose
a
given
fixed temperature T t. vaporization
at
material
undergoes
Examples
the
a
transition
at
a
that come to mind are fusion,
boiling
point,
first-order
phase
transitions, and allotropic modifications,
all of which will be
discussed
change
later
in
by
a heat
accompanied
detail. flow
Each into
study at a fixed temperature t. holds
will
be
discussed
in
such
or
out
of
the
is
normally
system
under
The reason why this condition
Chapter
2.
The
energy
change
accompanying the transition is then given by
(1.20.1)
AEt - Qt - Wt - Qt - ~tPdv. Two special cases are of interest: experimentally conditions,
be
constrained
If the transition may
to occur under
constant volume
then (1.20.2)
AEtlv- Qtlv, which
shows
that
in this
instance
a heat
flow
is equal
to a
change in a function of state, namely the energy of the system.
146
, FUNDAMENTALS Usually
constant
it is difficult
during
antifreeze however,
a
transition
to counteract
of constant pressure.
where
P.xt -
reversibly.
The
P
so
Since
- AH[p-
entropy
determlned
the
widespread
of engine
simple matter
In this event,
blocks).
to m a i n t a i n Eq.
change
long
use
of
It is,
conditions
(1.20.1)
becomes
(1.20.3)
as
the
P is fixed,
transition
PAV-
A(PV),
is
carried
out
and
(1.20.3)
may
to read
Q~[p .
(1.20.4)
accompanying
the
transition
may
now
be
as
AS t - AEt/T t
or
the volume p r e c i s e l y
(P fixed),
then be rearranged
AE + A(PV)
(recall
cracking
a comparatively
AE - Qt - PAV
to m a i n t a i n
(V fixed),
(I. 20.5a)
(P fixed),
(1.20.5b)
as
AS t - AHt/T t
depending on whether volume or pressure
(b)
We
turn
to
the
is being h e l d constant.
determination
experimental
data involving measurements
of
transition
heats
of
at
constant
of
the
of heat
pressure.
entropy
from
capacity This
and
method
depends on the use of Eq. (1.20.5b) and of the relation (@S/ST)p - Cp/T,
Eq.
(1.18.26).
S - rTf Ti
(Cp/T)dT - rTfCp d2n T. Ti
For purposes
of
The latter may be rewritten
as
(1.20.6)
illustration
consider
a material
which
undergoes a transformation from ~ to ,8 at temperature T=~, melts at the temperature
T m > T~,
T m.
to determine
It is desired
and boils
at the temperature
the entropy
of this
Tb >
material
NUMERICAL CALCULATION OF ENTROPIES
147
at a temperature T > T b. temperature
range
[O,T]
For convenience we divide the total into segments 0 ~ T a ~ T ~
~ Te ~ Tb
T, where T a is some low temperature in the range 0.I-I0 K, below which it is impossible
to measure Cp accurately,
the numerical values become
small,
both because
and because of problems
in
maintaining low temperatures during heat capacity measurements. In the range theory and
0 ~ T a one generally
first proposed by Debye
extended
temperature
by
Sommerfeld
(1907) (1926)
resorts
to use
for nonmetallic to
metals.
of a
solids At
low
and in zero order approximation,
Cp - aT s + 7T,
(1.20.7)
where a and ~ are parameters which in principle are determined by the theory.
However,
these quantities long as Eq. straight
it is general practice
empirically
(1.20.7)
by plots
of Cp/T versus
llne of slope _a and intercept
plots
are shown in Fig.
which
Eq.
extrapolation
T z.
So
remains valid such a plot should yield a 7 (for nonmetals
usually, though not always, extremely small). (1.20.7)
to determine
1.20.1,
applies
which
in these
indicate
cases
7 is
Examples of such and
the degree
to
the extent
of
that is involved.
On the basis of Eqs. (1.20.6) and (1.20.7) we thus obtain (in the range 0 < T _< Ta)
ST.
- S o - ~Ta(aTZ + 7)dT -
(aTe/3) + 7T a.
(1.20.8a)
0
(Note
that
So - 0
only
under
the
conditions
prescribed
in
Section 1.21 dealing with the Third Law.) In the range T a to T=~ we obtain S (T=~)
-
S (Ta) - rjTc,~ (C~/T) dT,
(1.20.8b)
Ta
which requires an empirical determination of C = for phase ~ as P
a function of T before the integration
is carried out. At the
transition point T=~ under constant pressure
148
I. F U N D A M E N T A L S
1.6 O~
1.2
E o
0.8 Copper 0.4
O0
I 2
,
I 2
,
1
~
4
1 6
L
I 8
~
l
L
1 10
~
I 10
~
1 12
~
1 14
1
1 16
,
l 16
x
1 1
8
4.0 "0
o3.0 E
E. 2 . 0 I--
1.0 0
. 0
1 4
~
1, 6
8
t , 12 4 1
/
l
l 18
10
'0
7
8
0
E
6
-)
E
4
L.)
1.
4
2
1
l
6
L
I
8
,
b ,
1
[ 12
t
l 14
I
[
16
1
[
18
T2deg 2
FIGURE 1.20.1 Heat capacity m e a s u r e m e n t s of elemental metals. After W.C. Corak, M.P. Garfunkel, C.B. Satterthwaite, and A. Wexler, Phys. Rev. 98, 1699 (1955).
(Sfl - S=)T= ~ - Q=fl/T=p - AH=fl/T=fl. The c o n t r i b u t i o n S(Tm)
- S(T=p) = I ~"
in the range T=~ to T m is given by
(Cpfl/T)dT.
It is easy to see that the remaining (S I - Ss)~m - Q~/T m
(1.20.8c)
(at the m e l t i n g point)
(1.20.8d)
contributions
are
(1.20.8e)
NUMERICAL CALCULATIONS OF ENTROPIES
S(Tm)
S(Tb)
jb
149
(C$/T)dT
(for the liquid phase)
(1.20.8f)
Tm
(S v - S,)Tb -- Qb/Tb S(T)
-
=
S(Tb)
(at the b o i l i n g point)
(1.20.8g)
(C~T)dT
(for the gas phase).
ST
by
(1.20.8h)
Tb Thus,
we
obtain
(I. 20.8h).
-
So
addition
Eqs.
(1.20.8a)-
Wherever phase changes occur the increment
given by a term of the type Q/T; contributions (1.20.8a)
of
are
of the
in S is
in the intervening ranges the
form J(Cp/T)dT,
and
for T < T a, Eq.
is used.
The problem with this approach is that the difference
ST
- S o depends on the pressure under which the experiment is done, since Cp, Qt, and T t change as this parameter is altered. therefore results
conventional
to measure,
at a standard pressure
users of such information such as (l.18.10b), It
is
It is
or at least to report,
of one atmosphere,
introduce
all
and to let
corrections via equations
in order to evaluate S T for other pressures.
conventional
to
standard conditions
denote
values
of
ST
reported
under
(generally I atm) as S~.
It should be evident that a similar approach may be used in
the
determination
(1.20.4)
of
the
enthalpy.
and with the relation C p -
Beginning
with
Eq.
(8H/aT)p we see that at a
pressure of i atm,
.o
_ Ho o
-
aT~ 4
vT~
+ -T
+
f T=#C=OdT + Ta
P
Q%#
[P
+
j. o "a#
Note now that H~ is an arbitrary constant any convenient value. in principle,
By contrast,
+
. .. (1.20.9)
that may be assigned
S~ is determined,
at least
by the methods of statistical thermodynamics,
that S~ is uniquely determined. quantities
P c~
We may now combine
so
the above
to find the Gibbs free energy:
(1.20.10)
ISg
i.
FUNDAMENTALS
Tabulations involving the quantities shown in (1.20.10) are of great
importance
applications.
and
play
They are
large
generally
for (GT~ - Ho~/T,
listings
a
role
supplied
in
industrial
in the
form
of
Ho~/T, and S~~ over a specified
(~-
temperature range. To illustrate exhibit
the type of analysis
a representative
1.20.2
for
oxygen,
representation
set of heat
as
a
plot
is useful
for
of
the
that is involved we
capacity
Cp
data
versus
direct
log
exists
in three allotropic
T;
calculation
entropy of oxygen from the area under the curves. the element
in Fig. of
this the
Note that
modifications
in the
solid state, with transition temperatures near 23.6, 43.8, and 54.4 K, the last being the melting point of solid phase I. The boiling
point
of
liquid
oxygen
is
near
90. I
K.
An
extrapolation procedure was used below 14 K. As reader
an
illustration
is again
cryogenic
heat
of
referred
temperature
to Fig.
capacity
1.20.1,
measurements
analyzed according to Eq.
14
low
on
techniques
which Cu,
pertains Ag,
and
the to Au,
(1.20.7) as plots of Cp/T versus T 2.
I
1. . . . . Liquid
_
02
S.I
10
-6 E
s 8
Gas
i c~
\
1:3
6
5i j u
1:3.
t 4 So
I
0 -- --""
J
"~I1
1 2
1 Log
T
FIGURE 1.20.2 The molar heat capacity of oxygen. After W.F. Giauque and H.L. Johnston, J~ Am. Chem. Soc. 51, 2300 (1929).
NUMERICAL CALCULATIONS OF ENTROPIES
In conformity straight
lines
coefficient
with with
earlier
|~ |
statements,
nonzero
the
three
intercepts
which
~ of the linear c o n t r i b u t i o n
to Cp.
plots
represent
yield the
EXERCISES
1.20.1 For SO2(g) in the range b e t w e e n 300 and 1800 K the following relation is found to hold" Cp11.895 + 1.089 x 10-3T - 2.642 x 10-ST 2 cal/mol deg. Determine AH and AG for a process in which I mol of SO 2 is h e a t e d from 300 to 1500 K. 1.20.2 In the range 300-1500 K one finds that for O2(g) , Cp - 6. 148 + 3. 102 x 10-3T - 9.23 x 10-TT 2 cal/mol deg. Determine AH and AG for i tool of oxygen when the gas is h e a t e d from 300 to 400 K. 1.20.3 Find the change in entropy for H20(s,-10~ arm) H20 (s,0~ atm); take for ice as 9 cal deg -I tool-I. 1.20.4 Find AS for H20(s,-10~ arm) ~ H20(2,10~ atm), given that is 9 and 18 cal deg -I mole -I for H20(s) and H20(2), respectively, and that the heat of fusion is 1440 cal deg -I mole -I . 1.20.5 The molar heat capacity at constant pressure of gaseous NH 3 varies with the temperature according to the empirical equation Cp - a + bT - cT 2, where a - 8.04 cal/mol-deg, b 7.00 x 10 .4 cal/mol-deg 2, c 5.10 x I0 -s cal/mol-deg 3. What is the entropy change of 2 tool of NH 3 that is h e a t e d at constant pressure from 20 to 200~ 1.20.6 By how much does the enthalpy of 3 tool of Cl2(g) change when its temperature is increased at a constant pressure of I atm from 300 to 400 K? Its heat capacity at a constant pressure of i atm in this temperature range is 7.5755 + 2.4244 (10-3)T - 9. 650 (10-7)T 2 cal/deg-mol. 1.20.7 The normal boiling point of benzene is 80~ and the heat of v a p o r i z a t i o n at this temperature is 7353 cal tool-I. For CsHs(~) and CsHs(g), Cp is 36.2 and 20.3 cal deg -I tool-I, respectively. (a) Find AS for CsHs(2,70~ i arm) C6Hs(g,70~ atm), (b) Find AS for CsHs(~,70~ atm) CsHs(g,90~ atm). i. 20.8 Taking -~ Cp - 7.11 + 6.00 x 10-3T - 0.37 x 10+ST -2 cal/mol-deg for NH3(g), calculate H~ - H2s8.15. values at T = 200, 500, 700, and i000 K. Obtain an expression for C$ from the preceding C~ expression and use it to find E~ - E2s8.15- at the above temperatures. 1.20.9 For the reaction CO + (1/2)O ~ CO 2 at 25~ S~ - 20.74 cal/deg-mol. The heat capacities @in cal/deg-mol) are given as
152
I. FUNDAMENTALS
Oz(g)" C p - 7.16 + 1.00 x 10-3T - 0.40 x 10+ST -2 CO(g)" C p - 6.79 + 0.98 x 10-3T - 0.II x 10+ST -2 CO~(g)" C p - 10.57 + 2.10 x 10-3T - 2.06 x 10+ST -2. Calculate AS ~ for the reaction at 1000~ 1.20.10 Between 0 and 15 K the molar heat capacity in cal/deg-mol of a certain insulating substance is computed according to the extrapolation formula Cp(s) - 5.78 x 10-4T 3. For the solid above 15 K, C p - 0.0085T + 0.00030T2; for the liquid, Ce(~) - 14.50 + 0.0043T; and for the gas, Ce(g) - 12.00. The heat of fusion at 200 K is 1.837 kcal/mol; the heat of vaporization at the boiling point of 350 K is 7.14 cal/mol. Find the molar entropy of the substance in gaseous form at 400 K and at a pressure of 0.I arm, assuming the gas to be ideal. 1.20.11 Use the data given below to calculate $i00 - S O for NazSO 4 by graphical integration. Use the T 3 law to extrapolate Cp below I0 K. Temperature, K _Cp, cal/de~ Temperature,K Cp, cal/deg 13.74 0.171 52.72 7.032 16.25 0.286 68.15 10.48 20.43 0.626 82.96 13.28 27.73 1.615 95.71 15.33 41.11 4.346 1.20.12 For a certain substance A, Cp for the solid form is 0.196 cal deg -I mol -I at 15 K. From this temperature to the normal meltln~ point, 200 K, it varies with temperature (T,K) according to Ce(s) - 0.0085T + 0.00085T 2 cal deg -I tool-I. The heat of fusion is 1.800 kcal tool-I. The heat of vaporization is 7.05 kcal mol -I at the normal boiling point, 300 K. Find the entropy of A(g) at 350 K and 0.5 atm, assuming the gas to be ideal. 1.20.13 (a) In the range 0 to 15 K, the Debye relation C ~ - (12~4/50a)RT 3 is valid for the heat capacity at 1 atm. For CO, 8 - 103.3 K. (b) CO undergoes an allotropic modification of solid CO(a) - solid CO(~) at 61.5 K, with an associated heat of transltlon of 0.633 kJ/mol. (c) The melting point occurs at 68.0 K; the heat of fusion is 199.7 cal/mol. (d) The boiling point occurs at 81.0 K; the heat of vaporization is 1443.6 cal/mol. (e) The molar heat capacity at constant pressure of 1 atm has been tabulated as shown below for the low temperature range" cal C~
4.0
6.0
8.0
9.0
ii.0
13.0
14.0
deg-mol T(K) 22.5 30.5 39.5 45.2 52.3 57.6 60.0 An empirical equation for the heat capacity between 61.5 and 68.0 K reads C~ - 7. 1621621 + 0.0775629T cal/deg-mol. The
153
NUMERICAL CALCULATIONS OF ENTROPIES
liquid is c h a r a c t e r i z e d by a constant heat capacity of C ~ 14.445 cal/deg-mol. For gaseous CO an empirical equation is given by C~ - 6.79 + 0.98 x 10-ST -_ 0.ii_ x 10-ST 2 (T in K) - ~ - H~ -S ~ , G ~ - G o O at i00, 200, 300 cal/deg-mol. Determine H 400, and 500 K. 1.20.14 The accompanying graph (Fig. 1.20.3) specifies Cp/T versus T z for pure Ti metal and for Ti-Mo alloys at low temperatures. The Jump in Cp for the alloys is due to a s u p e r c o n d u c t i n g transition. (a) For the Ti(85)Mo(15) alloy determine AS c and AH c for the s u p e r c o n d u c t l n g - n o r m a l transition at temperature T c, assuming that S o for the s u p e r c o n d u c t i n g phase is the same as for the normal phase if the latter existed at 0 K. (b) Determine the difference in entropy for the Ti(85)Mo(15) alloy and the Ti(95)Mo(5) alloys at 3 K and at 5 K. [Recent microscopic theories predict that above the superconducting transition (T > T=), C p - ~T 3 + 6T, that at the critical temperature T c, ACp(T c) - 2.436Tc, and that for T < T c, C p - ~T 3 + a6T c exp (-bTc/T)]. 1.20.15 (a) Refer to Exercise 1.18.22 and show that w h e n the pressure is altered from an initial value Pi to a final i
!
i
3K
I I 1 I 4K 5K Atomic percent m o l y b d e n u m
20--
~
~ 5
I I i
J
~
_'
_
/~/
12--
"
1
9 ~o
,
_@ o
E
)E. 8 - ~
4 ---~
-
/
1 FIGURE I. 20.3
1
10
1 T2,K 2
!
20
i
1
30
154
, FUNDAMENTALS
value Pz, the enthalpy change for a Berthelot gas reads H~ - H i (9 RT=/128 P=)(I - 18 T c / T z ) ( P z - Pi). (b) Determine the q u a n t i t y Cp - C v for a Berthelot gas. (c) Show that Ce(P ) - Ce(O ) - (81R/32)(T=/T)3P. 1.20.16 For H 2 gas one finds the following values for C~/R at i a t m " T(K) 40 60 80 I00 120 150 C~/R(K) 2.56 2.56 2.61 2.72 2.86 3.06 Determine the change in molar entropy for H z when the temperature is altered from 60 to 140 K. 1.20.17 (a) At very low temperature, T _< 0/10, the molar heat capacity of a monatomlc solid insulator is given by the relation C v - 233.782 R(T/e) 3, where e, the Debye temperature, is a parameter that must be specified. Determine E, S, and F as a function of temperature for the solid in the range of a p p l i c a b i l i t y of this expression. (b) In the temperature range T _> 100 the relation C v - 3 R [ I - (I/20)(0/T) 2 + (I/560)(0/T) 4] applies. Repeat the derivation for this case. 1.20.18 The following data apply to zinc; all energies are s p e c i f i e d in cal/mol" C(s)- 5.35 + 2.4 x 10-3T AH~ - 1.765 at 692.7 K C(2) - 7.50; Ce(g) - 4 . 9 7 A H ~ - 27.430 at 1180 K Determine the entropy and G~ - Ho~ for zinc at 1250 K. 1.20.19 For CI 2 gas C~ may be represented by the empirical relation 8.85 + 1.5 x IO-4T - 6.8 x I04/T cal/mol above 25~ Determine H~ - H~9s, S~ - S~9e, G~ - G~ge for CI z. -
I. 21
THE THIRD LAW OF THERMODYNAMICS
The Third
Law of Thermodynamics
deals
with
events
at T -
0;
clearly, problems arise here because the integrating factor I/T of ~Q diverges
at T -
0.
We first investigate T -0. mass
For this purpose, which
coordinate
may z.
generalized.) the
case
where
be
the question of the a t t a i n a b i l i t y of consider a special system of constant
characterized
(The
following
by
a
single
argument
may
Let Z be the conjugate variable. only
mechanical
work
correspond to P and V, respectively.
is
deformation be
readily
Note
that in
performed,
Then,
TdS - dE + Zdz - (SE/ST)dT + (Z + dE/8z)dz.
Z
and
z
since E - E(S,z),
(1.21.1)
THETH'RD LAW OFTHERMODYNAMICS
In an adiabatic
15 5
(isentropic)
process with dS = 0, Eq.
(1.21.1)
becomes
(aElaz)]/(aElaT)}dz.
dT I - {[Z +
This
situation
conditions hope
to
is
of
particular
which prevent obtain
alteration
a
(1.21.2)
interest,
a heat
maximal
flow
change
into in
since the
only
system
under
can one
temperature
through
in z, and thereby diminish T to its lower limit.
Now observe integrable,
T-I(aE/aT)dT + T-I[Z + (aE/az)]dz is
that dS -
as follows from the fact that the second derivative
of S with respect to z and T in either order must be the same. It
then
follows
(aE/az)]}.
(a/az)[T-1(aE/aT)]
that
(a/aT){T-I[Z
This condition may be met by requiring
independent variables)
z +
=
(aE/az)
- T
Inserting
(T and z are
that
(1.21.3)
(az/aT).
(1.21.3)
+
into
(1.21.2)
we
have
for
an
isentropic
process
dT I - T [.(aZ/aT)z-.]dz C ' ~ I T ( a Z / a T )Iz d-z , ( a E / a T ) z
where
Cz
(aE/aT),
m
maintaining contains
the
is
system
an extremely
adiabatic
process
inexorably
at
heat
capacity
constant
important
z.
measured
Equation
lesson.
It shows
any
chiange
in
a
a
change
in
temperature,
produces
Such a change
the
(1.21.4)
deformation
in d e f o r m a t i o n coordinate
while
(1.21.4)
that
in a______nn
coordinate
of
the
z
system.
z can be achieved,
for
example, by changing the volume of the system or by imposing or altering isolated low
the
electromagnetic
systems.
temperatures,
(aZ/aT)z
remained
possible
to attain
Note as
that
it
nonzero the
field
on
if C z were
does
at
in
this
absolute
high
adiabatically
to remain constant
at
temperatures,
and
if
would
be
range,
zero
the
then
temperature
it by
suitable
156
I. FUNDAMENTALS
changes
in
z.
investigated
for
all
it is found that C~ varies
In
fact,
with
w h e n T ~ O, w i t h ~ a I. on w h e t h e r
however,
The a t t a i n a b i l i t y
(aZ/aT) z approaches
- T =-I, so as
to p r e v e n t
a runaway
F - E - TS for w h i c h
Integrability
(az/aT),
far
as T =
of T - 0 thus h i n g e s
situation Consider
dF - dE - TdS
of dF then demands
as T ~ O.
This
the f u n c t i o n
- SdT - - Zdz
that a 2 F / a T a z
of
- SdT.
- a2F/azaT,
(as/az)T,
I
so
temperature
zero more r a p i d l y than does Cz/T
q u e s t i o n m a y be r e s t a t e d as follows" state
materials
or
(1.21.5a)
so that
(1.21.5b)
dT - - (T/C,) ( a S / a z ) T d z .
In other words, approaches
T-
unless,
for all z,
(as/az)r
zero more r a p i d l y than does Cz/T in the limit of low
temperatures. linked
0 is a t t a i n a b l e
to
The
the
attainability
behavior
of
problem
the
is
thus
metrical
intricately
entropy
at
low
namely
that
temperatures. We n o w
invoke
another
for e v e r y s i t u a t i o n
experience
s t u d i e d so far,
of mankind,
( a Z / a T ) z or ( a S / a z ) T -~ 0 as
T ~ 0, and that for any T in this range 0;
clearly,
satisfied chemical
is
a necessary that
reaction
condition
(aS/az)T involving
-~ 0
as
changes
a A S / a n i - 0 (this will be further this
experience
we
see
that T -
rise to the s o - c a l l e d p r i n c i p l e zero. be
The s t a t e m e n t s
included
of
particular, its
lowest
approaches any
condition
0.
Further,
dealt w i t h
later).
of u n a t t a i n a b i l i t y
finite,
to be
for
B a s e d on this
gives
of a b s o l u t e
-~ 0 as T ~ 0 m a y
law:
asserts
that
degrees
system
as the
Kelvin,
tends
toward
the a
least value w h e n the s y s t e m is in
possible
energy
state.
any
n i at 0 K,
0 is u n a t t a i n a b l e ;
zero
given
T/C z ~ 0 as T
in mole n u m b e r s
Law of T h e r m o d y n a m i c s
temperature entropy
T ~
this
( a S / a z ) ~ -~ 0 and ( a s / a n ) ~
as part of a n o t h e r
The T h i r d
for
(aS/az)~
The
entropy
LAW OFT H E R M O D Y N A M I C S
THE THIRD
reaches
15 7
such a value with zero slope for the
limit T ~ 0. One
should
carefully
qualifications: zero. in. the
to energy attends
excited configurations
When considering most
the
statement
and
its
Nothing is said about S approaching a value of
The reference
temperatures
note
stable
to the fact that at low
may accidentally be frozen
the state of lowest energy we deal with
configuration.
For
it,
the
entropy
at
the
absolute zero of temperature has the lowest possible value and is independent By
of all z or n.
convention
the
lowest
value
of
the
entropy,
So,
is
generally taken to be zero, except for circumstances enumerated below.
This
statistical
convention
accords
thermodynamics.
is the possibility given material
with
Exceptions
of conflgurational
may be
predictions
in more
based
arise whenever
disorder,
than one
state
i.e.,
examples
that come
to mind often
involve
there when
associated
the same or nearly the same lowest energy at 0 K.
on a
with
Elementary
cases where
for one
reason or another a certain degree of disorder is maintained at 0 K:
(a) Helium,
high pressure.
which remains a liquid at T (b) Solid CO, H20 , or N20:
In these materials
two adjacent units may be in configurations NNO-NNO
that
temperature
differ is
ultimately
energy difference units
only
is so small
very
slightly
reached
at
energy.
which
even
When
this
a
small
is important the rate of rotation of the N20 that random
orientations
Glasses or mixtures such as AgBr + AgCI: supercooled
such as ONN-NNO or
in
the solid cannot reach the lowest possible
as
0 except under
liquids
or
solutions,
residual entropy of mixing.
are
frozen
in and
energy state.
(c)
These can be regarded respectively,
(d) Finally,
with
in principle,
a
one has
nonzero values of S O in materials where isotropic distributions occur latter
or
in which
factors
experimental
nuclear
are
usually
conditions
such
the temperature is changed. done in setting S O -
spins
deviate
ignored
because
randomness In
from
I -
0.
under
remains
These
ordinary
unaltered
as
these circumstances no harm is
0; by contrast,
in for cases
(a)-(c) the
158
, FUNDAMENTALS
disorder
is changed by rising temperature.
setting
So
-
experiments
0
in
case
(d)
needs
dealing with nuclear
A very
important
to
The c o n v e n t i o n be
revised
of
in
any
transformations.
consequence
of the T h i r d Law is that
it
denies the existence of a perfect gas at low temperatures.
For
a perfect gas we had seen earlier that
(1.21.6)
S - C ~n T + R ~n V + S c.
It is clear that (8S/8V) T does not v a n i s h as T ~ 0, in v i o l a t i o n of the Third Law. use
of
the
This conclusion does not, of course,
perfect
thermodynamic
gas
law
calculations,
experimental
results.
well
as
away
a
However,
from
means
it
of
does
T
prevent =
0
in
approximating
make
for
logical
defects in conventional discussions of the Second Law, b a s e d on Carnot
cycles
substance,
which
employ
a
whose very existence
perfect
gas
as
a
working
is denied by the Third Law.
One may adopt another viewpoint c o n c e r n i n g the Third Law" Consider
a general
process
state A to state B. entropies for S B.
by which
a system
A c c o r d i n g to Eq.~.~l.18.12),
is altered
from
the respective
are given by SA - SA(0) + J
CpAd~n T, and similarly 0 Let the system initially be in state A at temperature
T I, and allow the process to occur a d i a b a t i c a l l y and r e v e r s i b l y so that the system ends up in c o n f i g u r a t i o n B at temperature T 2. Since SA - S B for the reversible
SA(0) +
where
CpAd2n T -
SA(O)
SB(0) +
adiabatic process,
and SB(0 ) are the entropies
two states at T -
0.
adiabatic
can be found w h e r e b y
system
changes
achieved,
then
> S^(O), that
process
then
the
tntegrand through
it
above is
this
T2 >
0
to
T2 -
SB(O ) _ SA(O ) _
is possible equation
positive. process
for the system
in the
The question now arises as to w h e t h e r an
from
AS I
(1.21.7)
CpBd2n T,
AS
Therefore, the temperature
0.
If
1CeAd2n T.
to choose for
the temperature
the
is
initial
satisfied
with Ta - 0
this
this
of the
could
Thus,
if
value
SB(O)
T1 s u c h
because value
be
of
can be reached.
the
T1 and But:
THE THIRD LAW OF THERMODYNAMICS
this
violates
the
temperature.
I 59
principle
of
the
unattalnabillty
The only way to avoid this
impasse
of
zero
is to demand
that SB(0 ) cannot exceed SA(0);
then there exists no value T -
TI
process
for
which
the
adiabatic
A
~
B
reaches
zero
temperature. The leads
same
to
reasoning,
the
requirement
conclusion
based that
on the S^(0)
inverse
cannot
exceed
SA(0 ) -- SB(0 ) is the only one
two contradictory
claims.
process
conditions
must hold in all other circumstances.
AS
-
The
SB(O)
requirement
of
their
-
is
0
in
the
special
cases
the
original
application either
AS
version
of equilibrium
already
discussed
here.
One
cannot
of
assume
Eq.
be
conditions
state
Heat
One must be quite because
computed,
or
should
in
else,
a
These matters be
supplemented wherein
to an e q u i l i b r i u m
are nonaccessible
some
the
state
to e q u i l i b r i u m
changes do not fall w i t h i n
the
(1.21.8).
have stated that
T~(~
an important point.
(aS/azl) ~ 0 for all d e f o r m a t i o n
including mole numbers;
Cz
famous
AS - 0 for any process
so that corresponding
-
the
interferes.
but
In closing one should reemphasize
C,
of
(1.21.8)
states
earlier,
from a metastable
because metastable
fact
It therefore
that are reversible
in 1906.
cannot
nonattainment
scope of Eq.
adiabatic
(t.2t.8)
were
system passes
under
.
Theorem proposed by Walther Nernst careful
the
that
S^(0)
foregoing
theories,
equality
that for all general processes
-
The
Note that since SA(0 ) and SB(0 ) are
the
we may ascertain
SB(0 ) .
that reconciles
constants, now follows
B ~ A,
We
coordinates,
this in turn hinged on the experimental
>_ i).
In
Section
1.18
it
was
shown
that
- T(aS/@T)z, 9 therefore , (aS/aT), - T =-I must likewise approach
zero.
In other words, near the absolute zero of temperatur.e the
entropy,
for any process
whatsoever,
as far as its dependence
on temperature T is concerne.d, approaches i t s lowest value with zero slope.
,. FUNDAMENTALS
160
EXERC I S ES
1.21.1 It was stated earlier that no perfect gas can persist to T - 0 K because this would incur a violation of the Third Law. Yet helium gas, which closely approximates to a perfect gas, does not solidify on being cooled toward 0 K under pressure of less than 26 atm. The liquid helium phase also appears to violate the Third Law. What contradictions might be involved and how may they be resolved? I. 21.2 Is a van der Waals gas admissible as an appropriate thermodynamic entity? Back up your answer with proofs. 1.21.3 Specialize Eq. (1.21.4) to the case of an ideal gas and show how T varies as the pressure and as the volume are altered adiabatically. 1.21.4 From the results of Sections 1.18 and 1.19, establish that it is necessary to have Cp/T and Cv/T approach zero as T ~ O.
1.22
THE GIBBS-DUHEM
(a) An elementary the
problem
number
of
of
EQUATION AND ITS ANALOGS
application
determining
moles
of
the
of Euler's
the
volume
constituent
specified
for constant
a special
case a solution containing
chloride
dissolved
temperature
in water.
of moles each of H2SO4, NaCI,
theorem
of
a
and pressure.
the
constant)
the been as
acid and sodium the number
at fixed T and P, then
generalization
that
at
mole numbers n i of all species of the system. of the state of aggregation
This leads quite
fixed
volume V of the system should be a homogeneous is independent
in
and H20 (note how this forces us
we must also double the volume of the system. to
when have
Consider
If we wish to double
to maintain all concentrations
naturally
system
components
sulfuric
is found
T
and
P,
function
the
in the
This requirement
of the system.
In view of the foregoing we write out Euler's Theorem (see Section 1.4)
in the form
V - ~i n i(Sv/8n
i)T ~
To
Euler' s
simplify
notation
(1.22.1)
~i equation
we
introduce
the
shorthand
161
GIBBS-DUHEM EQUATION AND ITS ANALOGS
(aV/Oni)T,p,nj#i,
V i -
(1.22.2)
with which
v - E i
(1.22.3)
where V i is known as the Partial mola! vo!ume. defined
by
Eq.
(1.22.2)
may
physically
be
The quantity
regarded
as
the
effective volume that is to be assigned to one mole of species i
in
an
infinite
conditions.
For,
copy
of
the
mixture
under
prevailing
one must take account of the fact that the
volumes of the various components in solution generally differ from their volumes when pure; components
is not
usually
i.e., the sum of volumes of pure
equal
to
the
final
volume
of
the
mixture.
We will learn later how to determine V i and thereby,
to render
(1.22.3) physically significant.
We
now
turn
to
a
conceptual difficulties:
matter
double
distinguish numbers,
the
a
of
a
system.
functional
We
rendering V a homogeneous
of
functionally
on all
V
on
mole
To satisfy (1.22.3) dependence
of the
it is necessary to demand that
all V i also depend parametrically on T and on P. to maintain full generality,
therefore
function of the nl, and a
while retaining a functional and parametric V(T,P; nl,...,nl,...),
must
dependence
parametric dependence of V on T and on P. type V -
presents
yet doubling of T or of P will not
volume
between
frequently
Obviously, the total volume V depends
on T, P, and mole numbers; usually
that
In addition,
every V i must be allowed to depend
the n i.
Thus,
we
rewrite
(1.22.3)
more
explicitly as
V(T,P;
How
nl,...
is
the
,ni,...
)
"-
dependence
i
niV i(T
of
reconciled with requirement
Vi
P;
nl,
on
. . . ,ni,
. . . ) .
T,P,nl,...,nl,...
(1.22.4) to
be
(1.22.2), according to which T, P,
and n3#i are to be held constant during partial differentiation? The answer lles in the fact that the partial derivative depends on the fixed values assigned to T,P,n3 at which they are to be
162
,
maintained sets
of
during differentiation" different
derivatives values.
values
V i will
in
When T and P are a s s i g n e d
(TI,PI)
general
FUNDAMENTALS
or
assume
(Tz,Pz) ,
etc.,
different
numerical
The fact that T and P are to be h e l d fixed in (1.22.2)
does not preclude V i from altering
in value as one passes
one
a
set
remarks
of
parametric
values
to
different
set.
from
Similar
apply to the nj~ i.
(b) We now have one formulation for V in Eq. wish to introduce nl,...,nl,...)"
dV -
the
a second formulation From Eq.
(SV/ST)p,.j,~dT
(1.4.4)
(1.22.3).
We
derived from V - V(T,P;
it n e c e s s a r i l y
follows
+ (8V/aP)~,nj$ idP + ~ Vldnl, i
that
(1.22.5)
which is to be compared with the result derived from (1.22.3), name ly, dV - ~ Vi d n i i Consistency
i
+ ~ n Idv i. i is achieved
(1.22.6) only through
the requirement
nldV i - (@V/aT)p nj#idT + (8V/aP) T,nj#idP ,
which
(1.22.7)
reduces
to the form L nldV i - 0 w h e n T and P are fixed. i (1.22.7) is a variant of the G i b b s - D u h e m relation.
Equation
(c) The preceding unless
operations
are of limited
one knows how to determine
stage we begin with a definition
V " V/
where
that
the various
significance
V i.
To set the
of the molar volume"
nj,
(1.22.8)
the sum runs over all components
introduce
the
definition
component,
x i - nl/ .~ nj, and Eq. 3
for
the
in the system.
mole
(1.22.3)
fraction
of
to obtain
We now the
_ith
16:3
GIBBS-DUHEM EQUATION AND ITS ANALOGS
- ~i xIVi"
(1.22.9)
Note that if the system contains V
-
nIV/n I -
special
niV I and
Vl
-
only one species we may write
(SV/anl)T,P
-
Vl,
whence
in
this
case
VI - VI
(one-component
system).
(1.22.10) m
For a b i n a r y s o l u t i o n we p r o c e e d to determine follows"
m
V I and V 2 as
Starting w i t h V - xiV I + x2V 2,
(~V/~x2)T,p-
XI(~VI/~X2)T,P + X2(~g2/~X2)T,P +
Now at fixed T and P Eq.
(1.22.7)
reduces
V2 -
Vl"
(1.22.11)
to (1.22.12)
xldV I + xzdV z - O , whence
8Vi ) [ 8+ Vx2 2~aXl
~[aV1
Xl "a'vl dxl +----ax2 dx2 T P
aV2 dxl + ax2
] dx 2
But, w i t h 8/8x I r e w r i t t e n as
- a/Ox 2 and
D
-O. T,P
~
dx I -
- dx 2,
the
m
(1.22.14)
2x1(avl/ax2)T, P + 2x2(av2/ax2)T, P - o, whence
(1.22.11)
(aV/ax2)~.p
Inserting -
(I
(1.22.13) above may be
- v2
reads -
vl.
(1.22.15)
- x2)Vl
+
into
(1.22.15) (1.22.9)
x2[(aV/0x2)T.p
yields (1.22.16)
+ gl],
or
VI -
V
- x2(SV/Sx2)~,
In Exercise s i m i l a r l y that
(1.22.17)
P.
1.21.1
the
reader
is
asked
to
demonstrate
164
Vz-
,. FUNDAMENTALS
V + x~(aV/ax2)T,p.
(1.22.18) m
Note the p r e s c r i p t i o n for d e t e r m i n i n g V I and V 2"
Analysis
of the various solutions p r e p a r e d in the laboratory yields sets of values of x I and x2; for each such set the molar volume V of the
solution
obtains
to
be
determined
at
fixed
a plot of the type shown in Fig.
For V(x2)
is
any
curve
According
particular yields
to
value
the
(1.22.17),
- 0 yields VI, while
the
of
P.
One
then
1.22.1.
of x 2 - b,
value
T,
the
tangent
(8V/ax2)r, P
intercept
for
to
x2
-
of the tangent
the b.
at x 2
its intercept at x 2 - i (x I - 0) yields V 2
according to (1.22.18).
This is a very simple graphical m e t h o d
for finding V I and V 2.
(d)
An
alternative
approach
to
the
above
draws
on
the
d e f i n i t i o n of an apparent molal volume 4, via the r e l a t i o n
V - nlV 01 + n 2 ~ ,
(1.22.19)
/
/
v~
J J
~O ~~O
~O~q
~
/
O
b X2
FIGURE 1.22.1 be determined.
Plot illustrating how partial molal volumes may
165
GIBBS-DUHEM EQUATION AND ITS ANALOGS
where ~0 is the molar volume of component I in pure form.
Now
switch to molalitles by referring all quantities
at I000 g of
pure
mass
solvent
(i.e. , pure
i).
Then
the
total
of
the
solution of density p is given as Vp - i000 + raM2, where m is the molality and M2, the gram molecular mass of solute. pure
solvent
solve
we
(1.22.19)
have
correspondingly,
for 4 and
relations just derived.
substitute
V~nip 0 for V
For the
I000.
Next,
and ~0 from
the
This yields
lP(m)"po " P~
i000
(1.22.20)
m
Measurements
of all the quantities
on the right-hand side now
permit ~ to be calculated for any solution of interest. Once ~ is known one may obtain V 2 via (1.22.19)
as
I
V 2 - (OV/@n2)nl,T,p- 4 + n2(@~/@n2)nl,T,p- ~ + m(O~/Om)T, P. (1.22.21) VI may then be found from the expression niV I + n2V 2 - niV ~ + n2~ as
VI-
~o + (n2/nl)( ~ _ V2) - ~ o
-
where
(mzH
-
MI
(1.22.21)
is
the
/1000) (a
gram
. m(n2/nl)(a@/am)T,e
atomic
and (1.22.22)
(1.22.22)
/am)T.p,
mass
of
solvent.
are the relationships
For many types of solutions
Equations
of interest.
it is found empirically
(and
will later be shown to follow from theoretical considerations) that ~ is proportional to ~ , a law
is
encountered
(i/2~)(a4/a~). (1.22.22) -
§
it
Now
i.e., ~ - b + a ~ .
is expedient
one obtains
to
Whenever such
rewrite
in place
of
(a4/am)
(1.22.21)
as and
the relations - b +
(1.22.23a)
166
FUNDAMENTALS
,
and _
~
mSl~M
V I - V~ -
The
I
2000
advantage
(84/8~)T'P"
of
(1.22.23)
(1.22.23b)
is
that
a plot
of
4 versus
obtained from (1.22.20) after making measurements of solutions should
of different molalities
yield
a
straight
line
~,
in a variety
for two fixed compounds,
of
intercept
b
and
slope
(8~/8~)Top, which remain fixed, along with MI, V~, and numerical constants.
It is then a straightforward matter to calculate V 2
and V I for any molality m of interest. (e) What has been stated with respect to V may be carried over to other thermodynamic quantities. of these Section
is the 1.16;
so-called Gibbs
free
energy
G,
described
in
also be reintroduced
later.
We assume G to be a function of T, P, and mole numbers.
If it
is to be
this quantity will
Among the most useful
a homogeneous
function
of the
conformity with the Euler criterion,
latter
set,
in
we must demand that
G - ~ ni~i, i where
then,
(1.22.24)
~i " Gi "
(8G/anl)T,P,nj#i is also known
as
the chemical
potential, for reasons explained in Section 2.4.
This quantity
occurs so frequently in chemical thermodynamics
as to warrant
use
of the
special
symbol ~i.
We now recognize
that G is a
function of T, P, and n i; then
n dGWe
(SG/ST)p,nldT + (8G/SP)~ nldP + ~ ' i-i can
thus
relation,
immediately
write
out
(@G/@nl)T,P,nj#i dn i. (1.22.25) the
famous
Gibbs-Duhem
in analogy to (1.22.7)"
~ nld~i - - SdT + VdP. Since contrast
G
or to
G
is
V or
V,
(1.22.26)
not
easily
it
becomes
accessible
to
correspondingly
measurement, more
difficult
in
THERMODYNAMICS OF OPEN SYSTEMS
167
to measure or determine ~i-
We will deal extensively with this
problem at a later stage.
EXERCISES
1.22.1 Prove Eq. (1.22.18) explicitly. 1.22.2 Cite an example of a system for which the following claim is incorrect" Consider two systems at the same temperature and pressure containing the same chemical materials in identical amounts. When these systems with identical amounts and chemical constitution are combined, the total energy is twice that of each subsystem. What does this counterexample teach you? Explain in some detail and show what conditions must be met so that the above statement will always be correct. 1.22.3 Find an expression for the partial molal volume of a gas in an ideal gas mixture at total pressure P and temperature T. Use it to find the partial molal volume of argon in an ideal mixture of 0.50 tool Ar and 1.50 tool Ne at 0~ and a total pressure of 0.20 atm. 1.22.4 When 1.158 mol of water is dissolved in 0.842 mol of ethanol the volume of the solution is 68.16 cm 3 at 25~ If Vs2o - 16.98 cm 3 mol -I in this solution find Vc~ssoH. Compare partial molal volumes of the components with their molar volumes. The densities of H20(~) and C2HsOH are 0.9970 and 0.7852 g c m -s, respectively, at this temperature. I. 22.5 At O~ the density p of aqueous calcium ferrocyanlde can be represented by the relation p - 1.000 + 0.245c - 0.0215c 2, where c is the molar concentration. Calculate the partial molar volumes of solvent and solute, and the total volume of solution for c - 1/2, i, and 2. 1.22.6 The apparent molar volume, 4, of KCI in an aqueous solution at 25~ is given by the equation ~ - (V - I002.94/m) - 27.17 + 1.744 m, where V is the volume in cm 3 of a solution containing I000 g of water and m mol of KCI. Find expressions for the partial molal volumes of KCI and HzO as functions of the molality. Calculate the numerical values of VI and V 2 for m O, 0.I, 0.2, and 0.5.
1.23
THERMODYNAMICS
OF OPEN SYSTEMS
(a) In Section 1.16 we considered number
of moles
now generalize
of various
closed systems
components,
in which
nl, remains
fixed.
the We
to the case where the various n i are allowed to ~
168
, FUNDAMENTALS
vary. F,
This
means
and G must
components
n o w be
(see
the system.
that
functions
functions
Section
2.2
For e x a m p l e ,
of s t a t e
of m o l e
such
numbers
for a d e f i n i t i o n
we set G -
as V,
G(T,P;
of
E,
S, H,
the v a r i o u s
of this
term)
in
nl,...,nc) , so t h a t
c
dG-
For f i x e d nl, it
(SC/8P)T,nldp + ~. (8C/Snl) T pnj#• i-I ' '
(@G/ST)p,nldT +
is
also
chemical
(8G/aT)p,nl -
very
useful
potential
- S, a n d
to
(8C/8P)T,n i -- V,
reintroduce
the
as b e f o r e ;
symbol
termed
/'~.t " (8C/ani)T,p,n3#.. L " Ci. One
should
energy, be
note
that
(1.23.2)
~i H
in the n o t a t i o n
rewritten
the
#i b y
G i is
really
of S e c t i o n
1.22.
a partial Equation
molal
free
(1.23.1)
may
as c
dG-
- S d T + V d P + i~l~idnl;_~
this
is
an
relations designed closed,
extension F
to one
-
G
of
- PV,
apply
(1.23.3)
Eq. H
-
regardless
(1.18.4). G
+ of
TS,
Bearing E
whether
-
F a
+
in
TS,
system
mind
the
which
are
is
open
or
obtains c
dF -
- SdT
- PdV +
~. #idnl i-I
(1.23.4)
c
dH - TdS
+ VdP +
~. ~Idnl i-i
dE - TdS
- PdV +
~. #Idn• i-i
(1.23.5)
c
(1.23.6)
in w h i c h
#i -
(SF/Snl)T,V,no# i " Fi
(1.23.7a)
#i -
(SH/Snl)s,P,nj# i " Hi
(1.23.7b)
#i -
(8E/anl)s,v,nj# i " El,
(1.23.7c)
THERMODYNAMICS OF OPEN SYSTEMS
169
and where
(aE/aV)s.,,j
P--
I
(aF/aV)t.nj
-
(1.23.8a)
v I (aH/aP)s.nj I (ac/aP)T.nj T-
S--
(1.23.8b)
(OE/OS)v..j- (OH/OS)p,,j (aF/OT)v,nj-(OC/OT)p,nj.
(1.23.8c) (1.23.8d)
We examine in Exercise 1.21.1 the question whether or not a different for
each
(1.23.2)
symbol
of
the
(say #e, ~F, .us, ~-) should have been used
quantities
G i, F i, H i , and
it is simplest
adding dn i moles of component the
in
the process
of
and (1.23.7).
Experimentally and
E i appearing
nj~i
conventional relations
are
kept
to prefer
to realize
i under conditions where T and P
constant. Eq.
For
(1.23.2)
that
rather
in (1.23.7) as a representation
reason
than
any
it of
is the
for Pl.
(b) One should note again the topology of the structure of thermodynamic
theory.
The four basic
thermodynamic
functions
of Section 1.18 have been enlarged to allow for variations
in
composition of the system.
P,
Correspondingly,
the variables
V, T, S may be found from Eq. (1.23.8), and ~i may be determined via (1.23.2) or (1.23.7). matter the
of convenience
system.
Again,
The choice in each case is simply a
relative
to the constraints
E and H are
adiabatic conditions prevail.
functions
most
P, V,
S,
T,. n)
Table
1.23.1.
(82X/axlax3) - (82X/axjaxl) leads As
to
the Maxwell
in Section
useful
For constant T processes
and G that are the useful functions of state. of holonomicity
imposed
1.18,
(X ffi E, H, F, G; x specified
in
a limited number
of
these is useful,
among them the partial differentials
entropy in parts
(A) and (B) of the table.
Items extensions systems.
[i]
and
of earlier
[4]
in
Maxwell
Table
1.23
relations
when
it is F
The requirement
equations
only
on
represent to the
Item [2] may be rewritten in the form
case
for the trivial of open
,. FUNDAMENTALS
170
TABLE 1.23.1 Maxwell
Relations
for O p e n Systems
(A) See Eq. (1.23.3)
Na
i T,x i
-
Na [I]
[aT J P,x i
~:,p.=j
P,x i
T.P,nj
[o--P-JT,x i
-
[31
[2]
(B) See Eq. (1.23.4)
T,x i
V,x i
[aT ; V,x i
T,V,n~
[4]
T,V,nj
[~---J
T,x i
[6]
[5]
(C) See Eq. (1.23.5)
[~v] S,x i
S,P,n0
P,x i
[7]
[~--)
~ni S,P,n j
P,x i
_ ra~il -- [~'-p j
S,x i
[9]
[8]
(D) See Eq. (1.23.6)
~~ Na S,x i
S,V,nj
V,x i
A subscript
The s u b s c r i p t fixed.
x i means
nj means
that all mole n u m b e r s
that all mole n u m b e r s
[aV ;S,x i [12]
[11]
[lo]
Note"
S,V,nj
[~-S--) V,x i
are
except
to be h e l d
n• are
fixed.
to be h e l d
I 71
THERMODYNAMICS OF OPEN SYSTEMS
(1.23.9)
S i = (8~i/aT)p,x• and item
[3],
in the form
(a~/aP)T,x~,
V~-
(1.23.10)
w h i c h shows h o w Eqs. partial
molal
appropriate
(1.18.8)
quantities
to e m p h a s i z e
should be a l t e r e d S i,
V i.
.fixed. which
of state)
in w h i c h
By contrast, some
are k n o w n
(c) Several definition
G-
all
stage
such as aS/anl,
fixed
quantities
as d i f f e r e n t i a l
additional
quantities
represent
entropies,
abbreviations
immediately
W
-
extension
of
Y.(1)Didnl) v a n i s h
earlier
the
that
where
only
introduce
E be
mechanical
Hi -
(aH/Onl)T,P,no#i and
definitions,
identically
this is e q u i v a l e n t
Law
From the
that
function needed
consideration; First
etc.
Si =
introduced.
v i e w e d as the excess or deficit +
extensive
volumes,
(1.23.11)
the c u s t o m a r y
an
are he!.d
points will n o w be made.
H - TS it follows
(aS/ani)T,p,nj#i have b e e n As
is
a V / a n i, . . . , in
~i = Hi " TSI,
where
it
of the type a Y / a n i (Y is any
intensive
quantities
or all of the
variables,
this
the fact that the term "partial molal"
is r e s e r v e d for p a r t i a l d e r i v a t i v e s function
At
to apply to the
a
in the usual m a n n e r
is
any
may
of
state.
involved
we
the total e n t r o p y
now
be
to have Q - (AE process
to the r e q u i r e m e n t
function
work
for
Q
For may
under
i m p o s e d by the
case
therefore
f u n c t i o n S such
that
f f Q r - TdS.
(1.23.12a)
Then
aT;r - PdV
- ~ ~idnl. i
(1.23.12b)
172
I.
FUNDAMENTALS
There exists, however, an alternative identification.
One
may switch from the set of independent variables S, V, n• to the set T, V, n i by reformulating
the First Law of Thermodynamics
as
dE - T[ (8S/aT)v,.~ dT + -
-
(SS/SV)T,xldV
(SS/8nl)r,v,nj#idnl]
+
PdV + ~ #idnl i
(SE/8T)v,xldT +
(1.23.13a)
(8E/aV)~,x i dV +
~(SE/Snl)~,v,nj~idni.
(1.23.13b)
i As
usual,
match.
the
coefficients
of
all
differential
terms
must
Thus,
- T(8S/8T)v,xi
(8E/8T)v,xi
.. Cv.xi
(1.23.14a)
(SE/HV)T,x i - T(BP/HT)v,x i - P
(1.23.14b)
( S E / S n i ) T , v , n j , ~ i " ~i + T(SS/Sni)T,v,nj,~ i.
(1.23.14c)
Note that in (1.23.14a) an enlarged definition of heat capacity has been introduced.
Use of the Maxwell relation [4] of Table
1.23.1 has yielded (1.23.14b); this is a slight modification of the
caloric
Writing
equation
of
state
introduced
(8Z/Snl)T,v,nj~i- Z i, Eq.
(1.23.14c)
in
Section
1.18.
shows that ~ i -
El
- TS i. An alternative derivation of this relation is called for in Exercise 1.23.19.
Thus,
finally, (1.23.15)
dE - Cv,xldT + [T(SP/ST)v,xl - P]dV + ~ Eidnl. i One
should
carefully
note
that
it
is
not
permissible
to
identify ~Qr with Cv0xldT for reasons to be explored in Exercise 1.23.22. The
reader
should
be
able
to construct
the
analogs
of
(1.23.14) involving the enthalpy, and to derive the expression
dH - Cp,xidT + [- T ( a V / a T ) p . x i
+ V]dP
+
~. Hidn i. i
(1.23.16)
173
THERMODYNAMICS OF OPEN SYSTEMS
(d)
Lastly,
extensively (1.23.3)
in
we
cite
later
with respect
two
relations
sections.
If
to P keeping
we subsequently differentiate
we
will
be
used
differentiate
Eq.
T and all n i fixed,
and if
the resultant with respect to nl,
we obtain the first result of interest part
which
(see also Table 1.23.1,
[A] ) :
(a~/aP)z,.~
(1.23.17)
= v~. m
Starting with Eq.
(1.23.9) we write ~i/T - HI/T - Si, whence
[a(~,i/T)/aT]p,x i - (- HI/T 2) + (i/T)(aHi/aT)p,x•
- (a-si/aT)p,x i. (1.23.18) m
On
introducing
Eq.
(1.23.5)
in
the form (i/T)(aHi/aT)p,x•
I
+ (aSi/0T)p,xl, it is seen that the last two terms cancel; [a(~i/T)/aT]p,xl - - HI/T z, which
is a basic
relation
thus,
(1.23.19) that
finds
frequent
application
in
later sections.
EXERCISES
1.23.1 (a) The chemical potential has been v a r i o u s l y identified as (aE/ani)s,v,na , (@H/.@ni)s,p,n~ , (aF/ani)T,V,na , (aG/anl)T,Pn' 3 " Are all these quantltles identical or do they differ? Document your answers fully by means of appropriate derivations. (b) The chemical potential has also occasionally been defined as (aE/ani)T,v, n and (aH/ani)T,P,nl. Are these quantities the same as for (a~? Document your answer fully. 1.23.2 working with the Helmholtz free energy function show that : (a) ( a E / a n ) T , V - ~ - T ( a ~ / a T ) v , n (b) (an~aT)v, n = (an/a~)T, v {~- (a~/aT)v,n} -T-l(an/a~)T,v(aE/an)T,V, where 17 i ~/T (c) (aE/aT)v, n - (aE/aT)v, n - T-1(an/a#)T,v(aE/an)~,v >_ o. 1.23.3 Expand on the analysis of this section by examining cases where work other than mechanical (P-V) work is involved.
174
I. FUNDAMENTALS
1.23.4 The term ~ ~idnl is sometimes known as "chemical work". Is such a designation appropriate? 1.23.5 Suppose mole fractions rather than mole numbers were used as independent variables to indicate the c o m p o s i t i o n of the system. How would such a step affect the analysis? In particular, could one define a chemical potential by, say, 1.23. (a) Show under what conditions the g e n e r a l i z e d Gibbs equation TdS - dE - ZZldz i - ~ Pkdnk may be integrated to give TS - E -~Ziz i - ~Pknk . (b) Correlate these results with the conventlon~l defi{itlons for H, F, G. 1.23.7 (a) Prove that for any function of state ~ and with a set of conjugate variables (Yi,Yl), the following relation holds" Td(S/~)d(m/~) - iZ"fld(yl/~) - ~ k d ( n k / ~ ) . (b) Specialize the above to the case where ~ represents the total mass of the system, the total number of moles of the system, and the volume of the system. Take special note of the formulation for the latter case. 1.23.8 Let Z Z(T,yl,nk) be any functions of state of temperature T, deformation coordinates Yl, and mole numbers n[. Let Z ~ Z/n, with n - ~(k)nk, be the molar quantity, and let Z k " (8Z/ank)T- n be the partial molal quantity. (a) Prove that 'J' i~k with x k_- nk/n, Z - Z(k)XkZk . -- (b) Prove that d Z (8Z/OT)yl,nkdT + E(1)(aZ/ayl)T,y~r + E(k)Zkdx k. 1.23.9 ReTerring to the previous problem, let Z ~ Z/V, where V is the total volume of the system and let c k - nk/V. Prove_ that d Z (i/V){(aZ/aT)yl,nkdT + ~(aZ/ayl)z,y0#i,nk dy i +
~Zkdck }. 1.23.10 Examine t h e c o m p l e t e T a b l e o f Maxwell R e l a t i o n s b a s e d on Eqs. ( 1 . 2 3 . 3 ) - ( 1 . 2 3 . 6 ) . Discuss the utility of the various entries. 1.23.11 Discuss the question as to whether it w o u l d not have b e e n more suitable to define an increment in Gibbs free energy according to dG - - SdT + VdP + iZl ~idxl where c-i independent mole fractions appear as varia5~es rather than the c mole number n i. In fact, is there not a redundancy in the commonly used expression for dG? 1.23.12 (a) Derive the following relation (which is of interest in statistical thermodynamics) for a o n e - c o m p o n e n t system" ( 8 # / 8 n ) T , V - (V/n)Z(dP/0V)T,n . [Hint" Y o u will need several of the mathematical 'tricks' of Sec. 1.4; you need to recognize that the general equation of state interrelates T, P, V, and n; and you need to consider the fact that ~ = #(T,P,n).] (b) Show that for an ideal gas this genral result reduces to the conventional expression. 1.23.13 Show how the derivation of Eq. (1.23.7) can be h a n d l e d by use of the Planck Function introduced in Exercise 1.18.4.
THERMODYNAMICS OF OPEN SYSTEMS
I7
1.23.14 Prove that for the internal energy function the following Gibbs-Duh.em relation must hold; Ed(I/T) + Vd(P/T) -~.inld(~i/T) - 0. Show what variables, if any, must be held fixed for this relation to apply. 1.23.15 In this Section the internal energy function has been introduced in the form E - E(T,V), whereas in Section 1.18 it has been formulated as E - E(S,V). Considering that thermodynamic functions of state should be useful in deriving various intensive and extensive variables, are the two formulations equivalent? If not, which one is more fundamental? In a similar vein discuss the relation b e t w e e n H H(S,P) and H - H(T,P). 1.23.16 Consider the Grand Potential Function ~ - E - TS C -i~l~ini. (a) Derive relations for S, P, and n i in terms of appropriate derivatives involving ~. (b) Show that ~ - - PV. (c) Discuss cases where the function ~ may be of utility. 1.23.17 Prove that the Gibbs free energy is subject to the following requirements" r (ac,/aP)t,x~ ~__j n i (a-d/aP)t,xt tI1 -
I
r
(ac/aT)p.. i _tZ.1 n~ ( ac/aT)p,x, . 1.23.18 Why can one not equate Eqs. (1.23.9) and (1.23.10) with items [5] and [9] of Table 1.23.1, respectively? 1.23.19 (a) Establish relations between (aZ/an• T ena and (aZ/anl)T v,n~ for z I E,S. (b) Derive Eq. (1.23.14) using the results of ~a). (c) Prove that (1.23.13a) is equivalent to the following relation" dE I (aE/aT)v,xld T + (aE/aV)T,xtd v + T-(i)(@E/@ni) T,V,n~#idni 9 1.23.20 rntroduce the partial molal quantities Z i by=the definitions (SZ/@nl) T p n and a related set of quantities Z i (@Zl/@nl)T v n~Find 'relations for S,, in terms of ~i, Hi in terms of El, and Hi, H i in terms of E i. 1.23.21 Using the results of Exercise 1.23.20, prove that i. 23.22 Prove that the following relations are mathematically correct: dE - TdSoF - PdV + E~idn• ; dHTdSo~ + VdP + ~ • wherein dSoE - (Cv x./T)~T - (OV/OT)p,xidP and dSo~ - (dp x /T)dT + (0P/0T)vx dV'." (b) Explain very , i , i carefully why tSis _relation is not very useful or even 'dangerous'. [Hint" Hi I (aH/anl)T,e,nj ; what are the variables actually occurring in the expression for dH?]. (c) Show why it is not permissible in Eq. (1.23.15) to set ~Qr I Cv,x• [Hint" Examine the Second Law and note where the entropy enters Eq. (1.23.15) implicltly.]
176
, FUNDAMENTALS
1.24
A R E M A R K CONCERNING
SYSTEMS WITH V A R I A B L E
In See. 1.23 we introduced thermodynamic systems
of
variable
composition.
COMPOSITION
functions of state for
For
example,
the
energy
function was w r i t t e n as c dE - TdS
where
- PdV + ~ ~idnl, i-i
the
index
i
We
principle
be altered
by
the
now
runs
species.
take
occurrence
(1.24.1)
over
all
chemically
cognizance
of
the
distinguishable
fact
that
n• can
in
in the amount dn i by two mechanisms:
of
chemical
reactions
totally
(i)
within
the
system w h i c h change n i in the amount dNi, and
(ii) by transfer
across
i
boundaries,
reservoir written
of
containing
dN i moles species
in the alternative
of
i.
species
Thus,
Eq.
from
or
(1.24.1)
to
may
a be
form
c dE - TdS
Some
- PdV + ~ pi(dN i + dNi). i-i restrictions
apply:
which dN i - 0 for all i.
(1.24.2)
Consider
Then Eq.
a closed
(1.24.2)
reduces
system
for
to
c dE o - TdS
- PdV + ~ pldNi. i-I
On the other hand,
(1.24.3a)
the e x p r e s s i o n obtained in Section 1.18 for
the energy of closed systems
dE o - TdS
is given by
(1.24.3b)
- PdV.
Consistency between
(1.24.3a)
and (1.24.3b)
then demands
that
c ~idNi - 0.
(1.24.4)
i-i This
requirement
necessary
be
and sufficient
when reactions (1.24.4)
will
and
shown
in
condition
Section
2.9
to be
for e q u i l i b r i u m
take place totally w i t h i n a system. the
simplification
that
leads
from
both
a
to prevail Constraint
(1.24.3a)
to
A GENERALIZATION OF EULER'STHEOREM
I "/1
(1.24.3b) are in accord with the previously anticipated concept that changes
in internal
energy can take place
system exchanges heat, work,
only when
the
or matter with its surroundings.
Any processes occurring totally within the system do not change its internal energy E.
In view of (1.24.4)
well have been written Eq.
(1.24.1)
one could equally
for quasistatic processes
in the form C
dE - TdS - PdV + ~ #idNi. i-i However,
(1.24.5)
there is no harm in carrying along sets of terms that
ultimately vanish, and to continue using (1.24.1) with dn i - d ~ i +
dN i.
Similar
remaining
commentary
differentials
applies
of the
to
expressions
thermodynamic
for
functions
the
H,
F,
and G.
EXERCISE
1.24.1 Provide a discussion that addresses the issue as to where the driving forces leading to chemical reactions within a system 'come from', and describe 'what happens to them' as the reactions proceed.
1.25
A GENERALIZATION OF EULER'S THEOREM
(a) For later use it is important to generalize the exposition on
Euler's
theorem,
f(al,...,an;Xl,...,xm)
as
shown
below.
Consider
a
function
which meets the following requirement:
fk " f(al,'-',an;kxl,''-,kxm)
- khf(al, ...,an;xl,.-.,xm) - khf;
(1.25.1) i.e.,
f
is homogeneous
xl,...,x m. Next,
Z i-I
of
order
h
in
the
set
How do we generalize Euler's Theorem? differentiate
dai + [aaIJ aj#i,kx r
Eq.(1.25.1)
Z r-i
as follows:
d(kxr) (kxr)
ai,kxs# r
of variables
178
,.
-kh
dal + k h
Z
i-I
dxr
Z
r-i aj#i, Xr
FUNDAMENTALS
al,
Xs#r
+ hkh-lf(al,...,a=;xl,...,xm)dk.
(1.25.2)
Note that on the right side we also had to consider k as a variable because on the left k is part of the operand of the operator d. Since d(kxr) - kdx r + xrdk, we can use this relation and collect coefficients of the various da i and dx r. We obtain
n {pfk I i-~l t~al
r-I
k h @[~al]} _
m {k [-aafk ] dal +r-~l (kxr)
(k~r)'l - hkh-i de - 0.
.
k h a[~r]} d x r
(1.25.3)
Since the dal, dxr, and dk may be varied arbitrarily one can satisfy (1.25.3) only by having their coefficients vanish individually" Thus, fk ]
-
k,,
la 1 - la ] - hkh-lf. r~l Xr -
8 (kxr)
[i - l,...,n]
(1.25.4a)
[r- l,...,m]
(1.25.4b)
(1.25.4c)
On inserting (1.25.4b) into (1.25.4c) and canceling out a common factor kh-i we obtain Euler's equation in the form
m _~ Xr r i
a[~=] - hf.
(1.25.5)
A GENERALIZATIONOF EULER'ST H E O R E M
I ~9
We note the following:
(i) Only the variables
k appear in the foregoing the result
cited
in Eq.
summation; (1.4.22);
that f must be an intensive assigned to k in kx i.
(ii) if h (iii)
quantity
in
i we recover
if h -
0 this means
independent
of the value
For such functions
0
xr
homogeneous
(h-
0).
(1.25.6)
r-I
Special note should be taken of Eqs.
(1.25.5)
and (1.25.6).
(b) We now develop some general thermodynamic applicable
to solutions
with
numbers
mole
freedom. I.
Readers
nj
of c components that
involve
2
expressions
containing additional
species degrees
j of
should check each step of all derivations.
Let B represent
an extensive
thermodynamic
variable;
let Yl represent the !th additional thermodynamic variable other than mole number nj; then one can express B either as (1.25.7a)
B - B(yl,...,y,;nx,...,n=),
or as B -
B(yl,...,y,;xx,...,x=_
(1.25.7b)
x,n),
c
wlth n -
no, x 3 i no/n.
Thus,
j-I (i)
dB
-
We can now write
dy i +
i~.
', Ha
--
dn3, j --I
Yk#i n j
(i. 25.8a)
Yl,nk#j
or
dB
-
dYl +
iy
Ykr ,x3 n
c - i 018_~al j-I
dx3 +
Yl ,Xk#j ,n
Na
(1.15.8b) Yi ,xj
180
, FUNDAMENTALS then Euler' s
(ii) If all the Yl are themselves extensive, Theorem as applied to (1.25.7a) yields
BIZ
Yl
iI[
Yk#i ,ni
and thereby simplify
7~ i i
Yl ,nk#j
n.
+
If,
on
(1.25.9b)
Yl .xj
Yk#i 'xo ,n
variables, I
(1.25.9a)
nl,
(1.25.8b):
Yl
(iii)
B
Z j I[
for B as specified in (1.25.7b), we apply Eq. (1.25.6)
whereas,
B-
+
the
hand,
other
the
Yl are
then, on account of (1.25.6) Eq.
Z
~
1Yl. nk,~j
j-I
n3, so that
all
intensive
(1.25.9a) becomes
" B- ~n-B ~
0{~nj1
Y~ .nk# O
(1.25.10a)
(Yl intensive) , whereas
B- aH
(1.25.9b) now reads
n,
so that
Ha
I
nB
-- I
B -
Yi' xj
Yi' x3
(1.25.10b)
(Yl intensive). Notice
that
specified holding note
partial
only when
only
the
molal
properties
the partial
intensive
of
derivatives
variables
fixed;
B
are
are thus
properly
taken while one
should
(1.25.10b)
with
Note further that if all Yl are intensive variables
then
the
difference
between
(1.25.10a)
and
regard to the quantity labeled as B. Eq.
(1.25.10a) may be differentiated
to read:
C
_ Z ~. [an,]
aB Yi ,Xk#j ,n
s=l
[axa) Yl,Xk~j,n
(z.25.zl)
A GENERALIZATION OF EULER'STHEOREM
W i t h n, - x,n,
(an,/aXj)yl,xk#j - 0 for (J ~ s), or n (for j - s),
or - n (for j - c)
a[a_,~]
l 8 [
[explaln
this last result!],
we now find
(1.25.12)
n(B,j - Be).
I
Yl, Xk,~-1 2.
Suppose
thermodynamic (1.25.7a) apply,
next
function
that
which
or (1.25.7b);
now Eqs.
If
all
Euler r e l a t i o n
the
Yl are
(1.25.6)
(1.25.8a)
an
.intensSve
specified
extensive
by
and (1.25.8b)
variables,
Eqs. still
function.
we
use
the
c
Yl
+
Yk#i ,n~
If we switch the case
7.
in going from
Yi +
(ii) If, however, on account
of
to mole
fractions
to (1.29.9b),
then,
as was
we obtain
n.
(1.25.13b)
Yi'x3
the various
(1.25.6),
(1.25.13a)
Yl, nk#,~
(1.25.9a)
Yk#t ,x3 ,n
simplify
nj.
j-1
from mole numbers
0 -- i~.l
0 -
be
to find
'
7.
then,
represents again
but we replace B by B m B/n for the intensive
(i)
0 -
B
may
Eqs.
Yl are intensive (1.25.13a),
and
variables, (1.25.13b)
to
.,. 8[~n3] ~c
jl
n~,
(1.25.14a)
Yl ,nk#i
or to
0- Ha
n. Yl,X3
(1.25.14b)
182
, FUNDAMENTALS
Equation (1.25.14b) is of particular importance" If B is an intensive thermodynamic variable, then Eq. (1.25.8b) is given by
dB - iZ I -
dy i +
(1.25.15)
dxo,
j--
Yk#i ,x3
Yi ,Xk#j
where it is implied that n is held fixed. (iii) We take note of the following restrictions are intensive) 9
~
p'~,'nl -
lenj
,,.. ,, '[~]
J
Yi, nk~i
"
n
(all Yl
'-~:,,.,:,
- --r n
-n
Yl, nk#i
Yi, nk#j
(1.25.16a)
'[~I
.
Yi ,Xk~3
r~ . [Sxj
J
.
.
i o[~,I
-
B3 -- B c 9
n
Yi ,Xk#j
Yi ,Xk#3
(1.25.16b) Thus, we could equally well put Eqs. (1.25.8a) and (1.25.9) in the form 2 a[ ] I c Z [aylJ dyi + n Z Bdnj i-I Yk#i ,n3 j -i
dB-
_ B_ dn,
n
(1.25.17a)
and
dS -
iZ I
dy~ +
--
j=,
(Bj
- Be) dxi
Yk#i' xj
2
af
~
c- I
- iZ I ~a-~i] -
dy• + Yk#i ,xj
I
j-I
Bjdxj.
(1.25.17b)
LEGENDRETRANSFORM AND STABILITY CONDITIONS
1.26 (a)
I
THE LEGENDRE TRANSFORM AND STABILITY CONDITIONS In
this
section
we
concern
ourselves
stability of a system at equilibrium. we
8~
must
first
deal
with
the
with
problems
of
By way of preliminaries
topic
of
generalized
Legendre
transforms. Let Y(Xo,Xl,... ,xt) be a thermodynamic function of interest that
depends
solely
on the
extensive
set of variables
{xl}.
Then t
dY- i7.o_
dx i x3#i
t ~ pidxl, i-O
(1.26.1)
wherein (1.26.2) We now introduce a (partial) Legendre transform Z of Y by the definition n
Z(Po,Pl,...,Pn,Xn+1,...,xt)
- Y(xo,Xl,...,xt)
with the Pl specified by (1.26.2). a
function
replaced
in which
by
their
differential of Z.
the
first
conjugate
-
~ PlXi,(l.26. 3) s i
Equation (1.26.3) represents n variables
quantities
p 9
of
Y
have
Now
take
n
i -I
the
This yields
dZ(po,...,Pn,Xn+1,...,xt) - dY(xo,...,x t) - 7. i-O t n n t -
been
"
" 9
xldpl-
n
pidxi-
7. i-O
xldpl
n
i ~n+l pldxl - i~O x~dp~.
i-O
(1.26.4) Accordingly,
Po,
9 9 9 ,Pn,Xn+l,
9 9 9 ,Xt)
-
"
Xk
for k _< n
(1.26.5)
184
I. FUNDAMENTALS
818---~'-k}I~ From Eq.
Lax
j
-
(1.26.6)
for k > n.
(1.26.1) one obtains
(1.26.7)
ta-- J"
On a second differentiation of (1.26.5) and with respect to Pk by
use
of
(I. 26.7)
one
arrives
at
the
very
important
relationship a2z
ap~
i -
-
a2y/ax~ (k
_< n),
(1.26.8)
showing that the second derivative of Y with respect to x~ ha_____ss a
sign
oDDosite
to
that
of
the
Les
transform
Z
with
respect tO the conjugate variable pw. (b)
We
now
illustrate
applying these results
the
preceding
to the energy E -
methodology
by
E(S,V,nl,...,nt)
and
entropy S - S(E,V,nl,...,nt) , both of which depend on extensive variables.
Now, at equilibrium,
a
with
maximum
respect
includes
a demand
example,
if
transferred
we
to
S for an isolated system is at
the
for uniformity
partitioned
the
energy from one half
imposed
constraints;
of properties. system
in
two
this
Thus,
for
halves
and
to the other half,
we would
violate the equilibrium condition and the system would then be at lower total entropy than in its uniform equilibrium state. Were
this portion removed one would
and the condition of uniformity violated. i
achieve
phase
separation
of composition would
then be
Thus,
S(E-AE,V,xz,...,xt)
+ iS(E+aE,V,xz,...,xt)
_< S ( E , V , x z
.... ,xt).
(1.26.9) As AE ~ 0 one may rewrite this in the differential
form
105
LEGENDRETRANSFORM AND STABILITY CONDITIONS
S(E,V, lxi}) - (AE)S'(E,V, lxi}) + ~1 (AE) 2S "(E,V, lx~}) + ... + S(E,V,{xs}) + (AE)S'(E,V,{xs})
+ ~i (AE) 2S " ( E , V , {x i})
(1.26.10)
+... _< 2S(E,V,[x i}),
on expansion in a Taylor's series in the variable E; the primes indicate first and higher order partial derivatives. (1.26.10)
Equation
simplifies to
(82S/SE2)v,xl _< O. A derivation
(1.26.11)
similar
to
(1.26.10)
for a transfer
of volumes
shows that (82S/SV2)E,xl _< 0.
(I. 26.12)
In precisely the same manner one finds that (~2S/~n2)s,v,n3# i < O.
(1.26.13)
The foregoing
extensive
variable
shows that no matter what particular
is altered,
S is always
concave.
We now note
some
immediate consequences of those equilibrium requirements. P i Since dS - ~ dE + ~ d V
t E j V,x i
~~
dnl, it follows that
_< O, (1.26.14) -
-
- T2
V,x i
"
T2
Cv
V,z i
or
C v >_ O;
(1.26.15)
i.e., the heat capacity of constant volume of a uniform system can only be zero or positive.
In Exercise 1.26.1 the reader is
186
, FUNDAMENTALS
directed to use Eq.
(1.26.12)
in similar fashion,
and then to
explore the resulting consequences. One
can proceed
similarly
with
energy,
stability criterion is turned around. I
except
that
the
For a uniform system,
i E(S-•S ,V, {n i}) + ~ E(S-AS ,V, {n i}) >_ E(S,V,{n i}),
(1.26.16)
which, by the argument developed in conjunction with (1.26.10), leads to (a2E/aS2)v,x i >__ O.
(I. 26.17a)
Similarly, (@2E/aV2)s,x i >__ O,
(aSE/an~)s,v,nj,~i z o.
(1.26.17b,c)
But (1.26.18)
(a2E/aS2)v,x i - (aT/aS)v,xl _> O, showing that S increases with T, as it must, self-conslstency with the manner a positive
if we are to have
in which T was introduced as
integrating denominator.
Similarly,
(a2E/aV2)s,xl - - (aP/aV)s,zl >__ o, which
shows
that
in
an
adiabatic
(1.26.19) process
pressure must lead to a reduction in volume.
an
increase
in
This, of course,
is a very comforting conclusion. (c) Now we must be extraordinarily of the thermodynamic E.
careful with the rest
functions that are Legendre transforms of
First, we can use the standard procedure that was employed
in deriving Eq.
(a2H/aSZ)P,xi ~_ O,
(1.26.17)
to find (1.26.20)
LEGENDRE TRANSFORM A N D STABILITY CONDITIONS
I87
whence,
(8T/aS)p,xl
>__ O.
(1.26.21)
But notice now that H is the Legendre transform of E and hence, subject to Eq. derivative
(1.26.8).
of H with respect
respect to V.
_
Thus,
Therefore,
the sign of the second partial
to P is opposite
that of E with
contrary to naive preconceptions,
(@2E/aV2)-I S,xl _ (a2H/ae2)s,x i _< 0,
(1.26.22)
or
(av/aP)s,x i _ 0;
of.
(1.26.15).
and
with
(1.26.21) The
Eq.
(1.16.19).
One
leads to T/Cp >_ 0, whence
Helmholtz
free
energy
F is
the
Legendre transform of E with respect to S and is a minimum for constant T.
We can proceed straightforwardly
to find
(a2F/aV2)T,x i >_ O,
(1.26.24)
whence
- (aP/aV)T,xt
>_ o,
which verifies
or
(av/aP)T,xl
_ 0.
(2.2.5a)
Here S i dS/dt represents the rate of entropy production in the time
interval
negative, no
work
involve
dt
for
the
corresponding
system;
and it vanishes at equilibrium. has heat
been
performed,
alone.
It
is
and
all
We then rewrite Eq.
transfers
reasonable
dE'/dt here with the rate of heat flow, Q, boundary.
be
In the present case
energy
therefore
S cannot
to
must equate
across the internal
(2.2.5a) as S - A(I/T)Q.
Next,
define a heat flux by the relation JQ - Q/A where A is the cross sectional area of the diathermic partition. that
the
temperatures
T"
and T" are very
Moreover, nearly
suppose
constant
in
both compartments and that the changeover from T" to T" occurs only over a small distance the
latter
being
~ perpendicular
essentially
at
the
to the partition,
midpoint
over
this
distance.
Then the product A~ roughly defines a volume V over
which
temperature
the
A(I/T)VJQ/2.
changes
we
may
now
write
S
-
In the limit of small 2 the ratio A(I/T)/~ becomes
the gradient V(I/T); moreover, production
occur;
the ratio w
of entropy per unit volume,
- 8 is the rate of
an intensive
quantity
[~
2. EQUILIBRIUM IN IDEAL SYSTEMS
that is of great theoretical in rewriting Eq.
(2.2.5a)
interest.
We have thus succeeded
in the more fundamental
form
(2.2.5b)
- V(I/T)JQ ~ 0. The preceding chain of reasoning a proper derivation of Eq. Chapter 6. aspects
(2.2.5b)
We nevertheless
departure,
because
one
is obviously very crude;
for
the reader is referred to
adopt this result as our point of
can
then proceed
of the theory of Irreversible
with
some
important
thermodynamics
without
having to cope with the full machinery of Chapter 6. In conjunction with Eq. (2.2.5b), note that JQ and V(I/T) m F t may be considered as conjugate variables, quantities
in that these two
occur as the product of a flux JQ and a generalized
(thermal) force or affinity Ft, such that schematically 0 - FtJ Q >_ O.
Note that 0 > 0 means either that F t > 0, Jo > 0 (i.e., T"
> T') or that F t < 0, JQ < 0 (i.e., T" > T"); heat
flows
from
the region
lower temperature. and F t vanish.
to that
When 0 - 0, equilibrium prevails;
both JQ
to
should
introduce
be
raised
the
as
to
temperature
whether
it
is
concept
in
a
nonequillbrlum situation.
The answer is in the affirmative
the following
conditions
portions occurs
sufficiency
of the system are very
very
of
the heat flux JQ.
question
meaningful
temperature
These facts give rise to the viewpoint that the
force F t 'drives' The
of higher
in either event,
slowly.
In
this
have been met"
large, event
T"
The
and the heat and
T"
if two
transfer
are
sensibly
uniform over both regions and most of the temperature variation takes place in the immediate volume A~ of the interface. The relation between F t and JQ cannot be determined from classical further
thermodynamics information
experimental
results,
such
alone. as
It
is necessary
microscopic
or further postulates.
to
transport
supply theory,
It is generally
accepted that for a system close to equilibrium there exists a proportionality between force and flux of the form Jo -
l~Ft,
(2.2.6a)
199
ACHIEVEMENT OF EQUILIBRIUM
where L t is a p a r a m e t r i c function independent of Jo or Ft, k n o w n as
the
phenomeno!ogical
process under study.
JQ
-
L~V(I/T)
where one
~ ~
-
~F~
(et/T 2)vT
-
-
for
the
irreversible
of Fourler's
(2.2.6b)
~VT,
(I~/T 2) is the thermal
formulation
present
-
-
coefficient,
Note further that
conductivity;
L~w of heat
Eq.
(2.2.6)
conduction.
is
In the
scheme we may set
-
(2.2.7)
J~/L~,
which requires
that L t _> 0 and ~ _> 0 in order that 8 _> O.
(c) We next examine
the
case
of
an
isolated
compound
system c o n t a i n i n g a sliding p a r t i t i o n that is initially locked and provides
for adiabatic
insulation
of two compartments
at
pressures P" and P", temperatures T" and T", and volumes V" and V".
The system is allowed to relax after slowly r e l e a s i n g
lock and changes
slowly
rendering
in both compartments
relation
dS
allowed.
The constraints
-
T-I[dE
dV" - O, as before)
+
Now,
PdV],
no
other
dS
- T -I
(8S/8V)E - P/T;
dS -- (I/T')dE"
Eq.
in accord with
forms
of
work
being
It should now be clear
+ (8S/aV")E, dV"
(2.2.8)
>_ o.
[dE +
PdV}
(2.2.8)
one
finds
(OS/OE) v -
I/T
and
then becomes
+ (I/T")dE" + (P'/T')dV"
(2.2.9)
+ (P"/T")dV" >_ O.
Finally,
the
in (b),
( 8 S ' / 8 E " ) v , dE" + ( 8 S " / 8 E " ) v . d E "
from
Entropy
are dV" + dV" - 0 (rather than dV" -
adopted
+ (as/av")~.dV"
diathermic.
can now occur
and dE" + dE" - 0.
that by the procedure
dS-
the p a r t i t i o n
the
with dE" - -
dE"
and dV" - -
dV"
one obtains
'200
2. EQUILIBRIUMIN IDEAL SYSTEMS
- (dS/dt)
- (I/T"
+ (P'/T"
This led
to
introduce
setting
A(I/T)
-
(2.2.10)
>_ 0.
in c o n j u n c t i o n up
of
Eq.
I/T'
-
with
the arguments
(2.2.5b),
the fluxes JE i dE'/Adt
affinities -
- P"/T")(dV'/dt)
expression,
the
convert
-I/T")(dE'/dt)
suggests
and Jw i dV'/Adt
I/T" and
A(P/T)
-
A(P/T)/2
V(P/T).
"
We further
production
per unit volume
by
thickness
of the partition).
introduce
0 - S/V-
that
-
P"/T ~ into
- V(I/T)
identifies
conjugate
w
(~ is the
leads
V(I/T)
to
by
the
the
We then obtain
and
requirements
fluxes
then
phenomenological
in
the
coefficients discuss the
V(P/T)
and
Equilibrium
is
then
0,
which
-
P"
condition
These
T"
FT -
-
T"
relations
to
assume
a
Fp -
and
P"
between linear
quantities
appropriate
to the
in much
call
entropy p r o d u c t i o n
form,
Since we require
Lzz -> O; for w h i c h
as
as and
termed
L
are
the
situation
further
attention
(2.2.12)
to
at hand.
detail
the
phenomeno!ogical
fact
We
in Chapter that
the
shall
6. rate
For of
is given by (2.2.13)
- FTJ m + FpJ w = LzzF 2 + (Lz2 + L2z)FpF T + L22F 2 >_ 0.
sufficient
Jw
forces
L2FT + L22Fp,
Jw-
various
we
as
equations
this matter
moment
well
that
postulated
LIIFT + LI2Fp; which
as
necessary
constraints.
JE-
JE
variables.
equilibrium are
small
(2.2.11)
force/flow
characterized
and Fp
the rate of e n t r o p y
- V(I/T)J E + V(P/T)Jw, which
we
and that we
P'/T'
such that for small 2, F T - A ( I / T ) / 2
that
0 to be n o n n e g a t i v e
it is b o t h n e c e s s a r y
and
to set
4L 1zL22 -
(Lz2 + L2z)2 _> O;
a derivation
is f u r n i s h e d
(2.2.14)
L22 _> O; in S u b s e c t i o n
(e).
ACHIEVEMENT OF EQUILIBRIUM
201
(d) As a final g e n e r a l i z a t i o n subsystems
separated
and p e r m e a b l e the
two
by
to one
species
compartments.
covered
by
a
material.
a rigid
to
extension
equilibrate
the case of two
that
is d i a t h e r m i c
in d i f f e r e n t
the p a r t i t i o n
adiabatic,
This c o n s t r a i n i n g
allowed
present
Initially
stationary,
we examine
partition
impenetrable
the
small
-
(I/T"
+ (~"/T" from w h i c h
and the s y s t e m
opening.
- ~"/T" ) (dn"/dt),
it follows
in c o n s o n a n c e
with
write
dn'/Adt
as
down
well
may
case.
be
That
equations
(2.2.15)
(2.2.16)
our the
as
is,
findings set
their
suitably one
of
of Section fluxes
conjugate
Jz"
2.1.
dE'/Adt
generalized
and
forces
The various remarks made earlier paraphrased
to
postulates
linear
Jn-
apply
to
the
Jn " Fz in the
present
phenomenological
be r e w r i t t e n
(2.2.17)
L43FT + L44Fn-
The rate of entropy production,
b a s e d on Eq.
(2.2.15),
may then
as
- FrJ z + FnJ n - I~3FTz + (L34 + L43)FTF n + L44Fnz >_ O,
L33 >_ 0,
In a d d i t i o n
of the form
Jz- L33FT + Lz4Fn;
subject
an
that at e q u i l i b r i u m
and F n - V(~/T).
section
By
- I/T") (dE"/dr)
T" - T" and ~" - /J",
V(I/T)
of
to obtaln
w = (dS/dt)
may
sheet
of earlier d i s c u s s i o n we invoke the r e l a t i o n dS - T -I
[dE - ~dn]
one
in
is c o m p l e t e l y
sheet is p u n c t u r e d
through
amounts
(2.2.18)
to the requirements
4L33L44 - (L34 + L43) 2 >_ 0,
L44 >- 0.
(2.2.19)
202
2. EQUILIBRIUM IN IDEAL SYSTEMS
The partition
generalization
of
is to be handled
(e)
We
considering
justify
a related
two-component,
(d)
to
the
in Exercise
expressions problem.
(i-
such
of
as
Compositional
one-phase mixture
>_ 0
ease
a
sliding
2.2.4. (2.2.14) stability
by of a
requires
1,2)
(2.2.20)
j-1 as the criterion for uniformity of composition. this may be expressed as
(dnl dn2)
Gii Gi2
Since
[Gij - (82G/SniSnj)T,p]
> 0 .
dnil dn2J
Gai G22
dn i and dn 2 are
itself must be positive elgenvalues
W
requirement
of
the
In matrix form
(2.2.21)
arbitrary
as well, matrix
is both necessary
the
as will
are
symmetric be
positive
G matrix
the case or
if all
null;
this
and sufficient.
We are thus led to examine the associated characteristic equation with eigenvalues
Gii - W Gi2
G2i G22 - W
(GII +
(2.2.22)
-0,
which may be expanded
W 2 -- W
W,
G22 ) +
into the form (Gi2 - G2i)
(GIIG22
-
(2.2.23)
G212) ** 0.
We now attend to the third term above on the right, with
the Gibbs-Duhem
(1.22.26)
xid~ilT,p
relation
at constant
T and P:
beginning Equation
reads
+ x2d~21T,p
-- 0,
(2.2.24a)
ACHIEVEMENT OF EQUILIBRIUM
203
or
xl [(8#l/Sxl)z,pdxl
+ (a#l/Sxz)z,pdx2]
+ (a#jaxz)T.pdx2] But
since
rewrltten
a/Ox I - -
+ x z [(8#2/axl)T,pdxl
- O.
8/ax 2 and
dx I - -
(2.2.24b)
dx2,
the
above
may
be
as
2[xl(81~l/Sx2)t,p
+ x2(8t~zlSxz)t,p]
= O,
(2.2.25)
or a s
nlG12 + n2G22
(2.2.26)
--O,
in the n o t a t i o n
of Eq.
By s i m i l a r
(2.2.21).
methodologies
we find
(2.2.27)
niG11 + n2G12 - O.
From
(2.2.26)
and
(2.2.27)
we o b t a i n
- nIG11 - n2G12
(2.2.28a)
-
(2.2.28b)
nlG12 -
n2G22.
On d i v i d i n g
(2.2.28a)
by
(2.2.28b)
GllG22 -
G22,
or
GllG22 -
G22 -
O.
We
see
that
the third
term
in Eq.
thus
we then find
(2.2.29)
(2.2.23)
vanishes.
are then left w i t h
W 2 -- W ( G l l
+
G22 ) -
for w h i c h
the two roots
(2.2.30)
0,
are
We
204
2. EQUILIBRIUM IN IDEAL SYSTENS
W - 0
or
(2.2.31)
W - G11 + G22.
We now insist on having W ~_ O; then
(2.2.32)
011 + Oz2 >_ O. However, sign.
to satisfy
(2.2.29),
G11 and G22 must have
the
same
Accordingly,
O11 >_ O,
022 >_ O.
Equations (2.2.14).
The
derivation which Exercises
2.2.1
(2.2.33)
(2.2.29) and (2.2.33) form an analogue of Eqs. reader
is
invited
leads directly and 2.2.2
to
to Eq.
for a better
undertake (2.2.14),
a
similar
and to work
understanding
of
the
topics under discussion.
EXERC I S ES 2.2. I Examine the following derivations yielding conditions of stable equilibrium" (a) Suppose half the volume of a system of total entropy S, volume V, and energy E is changed so that one half has an entropy (1/2) (S + 6S) and the other half has an entropy (I/2)(S - 6S). Prove that in second order approximation the energy of the total system has increased by (1/2) (62E/6S2)v(6S)2. (b) Since for a stable system of total fixed entropy S and total volume V the energy should be a minimum, show that the preceding quantity is positive and that the condition of stability may be rewritten as (6S/6T) v > 0. (c) Interpret the result. 2.2.2 Repeat 2.2.1 except that the Helmholtz free energy of the system is to be fixed and the temperature is to be kept constant, whereas the volume of half the system is to be changed to (1/2)(V + 6V) and that of the other half to (1/2)(V - 6V). (a) Prove that (a2F/aV2) T > O, and (b) that (av/aP) T < 0 are conditions of stable equilibrium. What inequality must be set on the isothermal expansion coefficient ~? 2.2.3 On the basis of part (d) of the text, prove that, at constant temperature, material flux takes place along the direction of decreasing chemical potential. 2.2.4 Generalize part (d) of the text so as to be able to handle a system which is divided into two compartments by a partition that slides with friction.
TI-IE CLAUSIUS-CLAPEYRONEQUATION
2.3
SYSTEMS
20
OF ONE COMPONENT
AND
SEVERAL
PHASES:
THE
CLAUS IUS-CLAPEYRON EQUATION According
to
the
Gibbs
phase
rule
the number
of
degrees
of
freedom of any system is decreased by one for every additional phase that is added.
Thus,
for a one component system, f -
2,
I, or O, depending on whether the system consists of one, two, or three phases.
For example,
for the case of liquid water,
the two degrees of freedom are temperature and pressure, of which may be varied over wide state of aggregation of water. are
required
to
coexist,
independently adjustable;
limits without
However,
then
T
both
altering
the
when water and steam
and
P
are
no
longer
the pressure of the closed system is
now determined by the temperature or vice versa - one now has only one degree of freedom. pressure
on
equilibrium steam
would
Thus,
the
water-steam
value
(by means
continue
to
condense,
to the temperature
present.
The
withdrawn
of
to maintain
were
raised
of a piston,
appropriate
heat
if at fixed T < 647.2 K the
system
at
T, until
condensation
above
for example), the
vapor
the then
pressure
only liquid water must
be
is
continually
the system at the fixed temperature
T.
After condensation of all steam the pressure will rise as the piston
is
pressure
pushed
against
is slightly
water would continue
the
reduced
water.
Conversely,
(by withdrawal
to evaporate,
of
the
if
the
piston),
as long as the temperature
T is maintained, by supplying the heat of vaporization from the reservoir.
Ultimately,
only steam remains
in the system.
If it were desired to have ice, water, and steam coexist, then there
is no degree of freedom left:
maintained
at the point T - 273.16 K and P - 4.58 torr.
this reason,
For
the triple point of water serves as a convenient
thermometric reference standard These
The system must be
matters
are
well
(see Section 1.2). summarized
pictorially
in
the
phase diagram for water, Fig. 2.3.1 (not drawn to scale), which is a representative plot of pressure versus three
solid
curves
which
T and P may be
separate altered
out
three
temperature.
large
arbitrarily
regions
while
The
within
maintaining
206
2. EQUILIBRIUMIN IDEAL SYSTEMS
X 217.7 a t m H20 Solid,/
1 otto
Gas
4.58 m m (nonlinear)
I
I'~ 273.16 373.15
273.15
64Z2
T ( K)---~ (nonlinear)
FIGURE 2.3.1 The phase diagram of water
(schematic).
water
in its solid,
forms.
hand,
if
two phases
independent;
the
loci
presence
of
are
to
two
coexist,
phases.
T and
dependence
of curves
experimental
of
or gaseous
functional
indicated by means the
liquid,
For
values
example,
P are
T(P)
in the phase
(T,P)
On the other or
P(T)
diagram,
compatible if
it
no
is
longer is
now
which are with
the
desired
to
achieve coexistence of solid and gas, it is necessary to adjust T and P so that they fall somewhere on the curve OT.
Solid and
liquid can coexist only if the (T,P) coordinates lie along TX; liquid and gas are encountered simultaneously only when lles
along
earlier:
TC.
T
represents
C represents
the
the critical
triple point
point T-
(T,P)
discussed
647.2 K, P -
217.7 atm, above which the gas cannot be distinguished from the liquid. An alternative
presentation
of information
is achieved
through Fig. 2.3.2, which shows plots of P versus V (the molar volume) for various temperatures near the critical point. shaded
region
indicates
an
excluded
domain,
pressure region in which two phases coexist: 473.2 K,
gas
i.e,
The
a volume-
for instance,
at
at molar volume V a coexists with liquid at molar
THE CLAUSIUS-CLAPI::YRONEQUATION
2g 7
H20
|
217.7(Pr 6 7 5 T(K) 84.8
647.2
15.3
,.,,,,
Vc V
FIGURE
~
2.3.2 Phase behavior of water near its critical point.
volume
Vb;
the
temperature:
region As
the
Vb
x I.
is richer in
If PI > P2 then xl/(l - xl) > xl/
These matters are also illustrated in Fig.
2.6.1.
EXERCISES
2.6.1 For benzene and toluene, the vapor pressures of the pure components are 118.2 and 36.7 Hg, respectively. Prepare a graph llke that shown in Fig. 2.6.1 and indicate the approximate compositions at which there is a maximum difference in the composition of the liquid and vapor phase. 2.6.2 For the equimolar liquid mixture of benzene and toluene what is the ratio of masses of benzene to toluene in the vapor phase? 2.6.3 The vapor pressures of pure liquids A and B at 300 K are 200 and 500 mm Hg, respectively. Calculate the mole fractions in the vapor and the liquid phases of a solution of A and B when the equilibrium total vapor pressure of the binary liquid solution is 350 mm Hg at the same temperature. Assume that the liquid and vapor phases are ideal.
2.7
TEMPERATURE DEPENDENCE OF COMPOSITION OF SOLUTIONS
We have just examined the effects of varying the composition of solutions varying
at constant T and P; we now consider
the
temperature.
This
situation
the effect of
is more
complex
in
that the vapor pressure of the two species and the composition of the two phases, as well as the total pressure,
are altered.
This comes
for example,
about because
a rise
in temperature,
will favor vaporization of the more volatile component,
thereby
enriching the gas phase and depleting the liquid phase of this component. though
Thus,
the
all x i and all x i (or Pi) are altered,
overall
chemical
reactions
would be
too
impose the
system occur.
complex
condition
to be
is An of
closed, analysis
and
even
of all
immediate
use.
though
these We
even no
factors
therefore
that the total pressure P be maintained
TEMPERATUREDEPENDENCE
constant.
23 I
Experimentally
this
may
be
achieved
by
having
present in the gas phase a third, nonreactive gas that does not appreciably neutral
dissolve
gas
increments
is
in the solution.
either
(through
a
metered
in
or
semipermeable
maintain the overall P values.
As T is altered, else
membrane)
Alternatively,
the
withdrawn
in
as
to
needed
the solution is
encased in a pressure vessel with a moveable piston,
which
is
readjusted so as to maintain a constant overall pressure. We
invoke
the equilibrium
#i(g) - #i(~) "
Then ( ~
- ~P
constraint
for each
species:
of Section 2.4)
(2.7.1)
#~/RT + 2n P i - #~/RT + 2n xl, so that for the contemplated changes
[ (a/aT)(/~/RT) ]p + (a2n Pt/aT)p
[ (a/aT)(#~/RT) ]p + (a2n x~/aT)p. (2.7.2)
I
Now let xl designate the mole fraction of i in the vapor phase; then Pi - xIP. then
It follows that (8~n Pi/gT)p-
(8~n xl/OT)p.
We
find
a
-
xi)
a
_ _ - * -
RT
p
__
-
RT 2
P
RT 2
"
(2.7.3) Here
we
second
first
utilized
criterion
for
Eq.
(2.5.3)
ideal
and
gaseous
then
and
introduced
liquid
the
solutions,
whereby the molar enthalples for the pure components, H i and H~, are equal, respectively, same constituent
to the partial molal enthalpies of the
in solution
(Hi) and in the vapor phase
(Hi).
Notice that the preceding derivation can also be applied to
any
two-phase
liquids, solutions.
a
mixture
llquld-solld
such
as
system,
two or
sets two
of
types
immiscible of
solid
In these cases the dashed and undashed quantities
refer to the two respective phases.
For the special case of a
solution in equilibrium with a pure solid the dashed quantities
232
2. EQUILIBRIUM IN IDEAL SYSTEMS
x i remain
constant and
Eq. (2.7.3)
then
reduces to the form
(8~n xl/ST)p,xj - A H ~ / R T z where AH~ is the enthalpy of fusion for component
2.8
i which freezes out as a pure solid.
LOWERING OF THE FREEZING POINT AND ELEVATION OF THE BOILING POINT OF A SOLUTION
(a) One of the interesting problems in solution thermodynamics is the change
in freezing and boiling points
which a solute has been added. shown
that
liquid
A
the
addition
causes
of
to
Extensive experimentation has
a material
a lowering
of a solvent
of
the
B
that
freezing
dissolves
point
of A;
in for
example,
A and B may represent water and sugar,
respectively.
We
for
how
look
an
analytic
relation
that
shows
much
the
freezing point is depressed when a given quantity of solute is dissolved in the solvent. We consider a two-phase A (e.g.,
system consisting of pure solid
ice) in equilibrium with the solution of B dissolved
in liquid A (e.g., sugar in water).
This requires the equality
of the chemical potential ~A in both phases: ,A'
~,
(2.8.1)
~A(T,P) - ~z(T,P) + RT ~n xz, where #A and #z are the chemical solid and in the liquid state, One
should
condition
note
(2.8.1).
the At
potentials
of pure A in the
respectively.
implication
constant
P,
of a
the
equilibrium
given
temperature
corresponds to particular composition, xz, of the solution, vice versa. investigate
Thus, x z becomes this dependence
a function of T; x z - xz(T).
further it is ~ propos
and To
to subject
(2.8.1) to partial differentiation with respect to T" {a[(~
-
- ~,)/RT]/aT}p-
(~
- ~)/RT:'
,, E~/RT:' -
(a.~n x z / a T ) p .
(2.8.2) In
this
expression
alternatively,
we
have
first
invoked
Eq.
(1.23.19)
or,
(2.7.3) in different notation; H z and H A are the
233
CHANGES IN FREEZING AND BOILING POINTS
molar
enthalples
quantities
of pure
enter
respectively.
here
Next,
fusion
of pure
change
accompanying
AB.
Lastly,
A;
we
the right.
liquid A
because we have
note
that
again
and pure
solid A.
correspond
These
to #i and ~a,
defined L~ as the molar heat this
the transfer
invoked Eq.
Note
they
is not
the molar
of
enthalpy
of pure A into the solution
(2.8.1)
to obtain the quantity
that x I depends
implicitly
on T;
on see
Exercise 2.8.1. Equation i
(2.8.2) may be rewrltten as
d~n x I -
- (~.~/RTa)dT,
(P constant)
(2.8.3)
f
where
the limits
situations" is
the
on the integral
correspond
to two different
T~ is the freezing point of pure A (x I - I) and T I
freezing
point
fraction of A is x I.
of
the
solution
for
whfch
the
mole
In Exercise 2.8.1, we pose the problem as
to why a change in T should result in a change in composition. We introduce a temperature dependence of L~ in first order through use of the Kirchhoff relation, - (Cp) I - (Cp)A
Section 1.18,
(OL~/aT)p
ACp, in which ACp represents the difference in
molar heat capacity of pure liquid A and pure solid A.
Under
the assumption that the variation of ACp with T may be ignored, we find L~-
L~ + ACp(T - Tf),
(2.8.4)
where L~ is the value of Lf at T - Tf. Thus, ~:Id2n
xl--
.[TT~[E~/RT 2 + (ACe/RT2)(T- T~)]dT (P constant). (2.8.5)
Define the lowering of the freezing point by
8 f - T~- TI,
(2.8.6a)
so that
T1 -
T~[1
-
(e~/T~)].
(2.8.6b)
234
2. EQUILIBRIUM IN IDEAL SYSTEMS
Equation
(2.8.5)
may then be i n t e g r a t e d
to y i e l d
- ~n xll P - [ (L~/RTf) - (ACp/R) ] (Tf - TI)/T I - (ACp/R)2n (TI/Tf) ]p -
[(L~/RTf) - (ACp/R)] [Of/Tf(l - Of/Tf)]
In
general
(O~/Tz)llP.
(BOp/R) 2n [1 -
-
it
is an e x c e l l e n t
small powers of 0f/Tf"
We obtain
approximation
(i-
x 2) --x 2.
Equation
to e x p a n d
(2.8.7)
...].
Further,
then reduces
- 2n x I -
to
(2.8.8)
x 2 = (~.~/RTf)(ez/Tz) + [ (E~/RTf) - (n~p/2R)] (ez/Tz) 2.
The r e p l a c e m e n t o f Eq.
2n x I by x 2 does limit the a p p l i c a b i l i t y
(2.8.8) to dilute solutions,
essential
in
(I - Of/Tf) -I = I + Of/Tf + ...
and 2n (i - Of/Tf) = - [Of + O~/2T~ + -2n
(2.8.7)
of
but this l i m i t a t i o n is c l e a r l y
if the theory of ideal solutions
is to be a p p l i c a b l e
to real cases. Equation
(2.8.8)
is a q u a d r a t i c
be solved to find 8f in its d e p e n d e n c e of all of the above a p p r o x i m a t i o n s to n e g l e c t inverted
Of-
the term in (Sf/Tf) 2.
equation on x 2.
in 8f w h i c h may However,
in v i e w
it is g e n e r a l l y a p p r o p r i a t e Equation
(2.8.8)
may
then be
to read
(2.8.9)
(RT~/E~)x 2.
Ordinarily, expressed
in terms
the
lowering
of
of the m o l a l i t y
the
freezing
point
m 2 of the solute.
is
We note
that m 2 - I000 n2/nIM1, where M I is the gram m o l e c u l a r w e i g h t of the solvent" MjI000
further,
for dilute
x 2 - n2/(n I + n2) = n2/n I.
solutions.
Hence,
Thus,
(2.8.10)
Of = (RT2fMjI000 ~.~)m2 - Kfm 2.
This respects.
relationship First,
in
the
is
x2/m 2 =
rather
remarkable
approximation
scheme
in used
several here
the
l o w e r i n g of the freezing point is a linear f u n c t i o n of x 2 or m 2. Second,
the p r o p o r t i o n a l i t y
factor
is d e p e n d e n t
solely on the
CHANGES IN FREEZINGAND BOILING POINTS
properties way
23
of the pure solvent
depends
on
the
(i.e.,
properties
of
on M1, Tf, L~) and in no
the
solute.
For
a
fixed
solvent Kf is thus p r e d e t e r m i n e d and is m a x i m i z e d for solvents with
high
heats but
freezing
of fusion.
there
associate
are
points, All
high
molecular
of this accords
exceptions,
arising
weights,
with most
from
cases
and
low
experiments, where
solutes
or dissociate.
(b)
The
foregoing
procedure
requires
small
changes
to
become applicable to the elevation of the boiling point for an ideal
solution
solvent. [~y - ~ ]
containing
nonvolatile
~I(T,P) + RT 2n xi(2) - ~ ( T , P ) where
2
and
Accordingly
g
refer
[note Eq.
RT
---
solutes
*
to
+ RT ~n x1(g),
the
liquid
and
-H1 m~
gaseous
0~n
phases.
[x1(g)/xl(2)]
(2 8 12)
m
,
RT 2
the
(2.8.11)
(1.23.19)],
.
P
solvent
vapor
alone
makes
up
the gas
phase.
that event xl(g) - i, and we can then set x1(~) ~ x I. (2.8.12) now reduces
(a2n xl/aT) P
-
~
8T
P
Suppose
and a volatile
The equilibrium constraint for the solvent now reads
In
Equation
to
(H~ - H -*i)/ RT2 = - ( ~ / R T 2 ),
(2.8.13)
where L v is the molar heat of v a p o r i z a t i o n of phase A from the pure
liquid
atmosphere,
into
the
gas
phase.
T - T b represents
We next
(a) rewrite
If P is m a i n t a i n e d
(C~-
introduce C~) ( T -
Kirchhoff's Tb),
one
the normal boiling point.
(2.8.13)
as (2.8.14)
- d2n Xll P - ( ~ / R T 2)dTIP , (b)
at
law
in the a p p r o x i m a t i o n
L v - L$ +
(c) introduce the elevation of the b o i l i n g
236
2. EQUILIBRIUMIN IDEAL SYSTEMS
point by the definition 8~ ~ T I - T b so that T I - Tb(l + 8~/Tb) , and
(d) expand
8b/T b .
(I + 8~/Tb) -I and ~n
(I + 8~/T b) in powers
of
This yie Ids
- ~n x I = x2 - ( ~ / R T b)(8~/T b) - [ ( ~ / R T b) - (ACp/2R)](Sb/Tb) 2.
(2.8.15) On
neglect
of
the
last
term
on
the
right,
the
resulting
equation may be inverted to read 8 b - (RT~/~) x2
(2.8.16)
and 8~ - ( R T ~ I / 1 0 0 0 ~ ) m 2 - Kbm2.
(2.8.17)
The various remarks made in conjunction with Eq. (2.8.10) also apply here with appropriate modifications.
EXERC I S ES 2.8.1 Explore the physical meaning of the relation Lf/RT 2 - (8~n xl/aT) P. Why does the composition of the solution change as the freezing point of the solution is altered? 2.8.2 (a) Determine the mole fraction of benzene in other solvents at I aim and 0~ with which it forms ideal solutions, given the fact that its normal melting point is 5.51~ and that A C p 0, H~ -H~ - 2366 cal/mol. (b) Determine the mole fraction under a total pressure of I00 aim, given the fact that V(soln) - V ( s ) - i0 cm3/mol of benzene. 2.8.3 A solution of 20.0 g of a certain solute (molecular w e i g h t 168.1) in i000 g of benzene (molecular weight78.1) has a boiling point of 80.40~ The normal boiling point of benzene is 80.I0~ (a) Predict the normal boiling point of a solution of I0.0 g of the same solute in i000 g of benzene. (b) Find the experimental value of K b for benzene. (c) Calculate the value of Kb, given that the heat of vaporization for benzene is 7.370 kcal tool-I at its boiling point. 2.8.4 An experimentalist reported a freezing point change of 1.02~ for a solution containing i0.01 at. % of sucrose in water. For pure H20 , H ~ - 1.4363 kcal/mol at 273.15
CHEMICALEQUlUBRlUM
23 7
K. Determine the molecular weight of sucrose from these data, and discuss the reason for any discrepancies compared to the molecular weight as calculated from the formula for sucrose. 2.8.5 Compare the approximation (2.8.10) with (2.8.7) by numerical computation of the value of O~ for a I molal solution of sugar in water. The heat capacities of liquid water and ice are 18 and 9 kcal/mol-deg, respectively. 2.8.6 The heat of vaporization and the heat of fusion of water are 540 and 80 cal/g respectively. (a) For a solution of 1.2 g of urea in i00 g of water, estimate (i) the boiling point elevation, (ii) the freezing point depression, (iii) the vapor pressure lowering at IO0~ Assume ideal-solution and ideal-gas behavior and assume urea to be nonvolatile. (b) Discuss the foregoing properties of a solution of 1.2 g of a nonvolatile solute of molecular weight 108 in I00 g of water.
2.9
CHEMICAL EQUILIBRIUM:
GENERAL PRINCIPLES AND APPLICATION
TO IDEAL GASES (a) One of the most important applications of thermodynamics to chemistry occurs some
general
chemical which,
in the treatment of equilibrium.
principles
reaction,
below.
Consider
vlrR I + v2rR2 +
We develop
the prototype
...= vlpP I + vgpP 2 +
for the reaction as. written,
R I, R 2,
of
...,
a in
... are different
chemical reagents, PI, P2, --- are different chemical products, and the Vlr , vlp are stoichiometry coefficients for reagents and products,
respectively.
It
is convenient
to abbreviate
above reaction by writing ~ viA i - 0 in which, the
v i are
negative
or
positive
according
species A i designate reagents or products,
the
by convention,
as
the
chemical
for the reaction as
written. We
allow
equilibrium
the reaction
to proceed
until
or to a steady state condition
it has
come
to
and then maintain
constant T and P; this latter restriction is often overlooked. The fundamental expression for the Gibbs free energy reads G = Z(1)ni~i, where
the mole numbers
are initially arbitrary. virtual displacement is given by
n i and chemical potentials
~i
The change in G which results from a
(see Section 1.16) for the above reaction
2.,~
2. EQUILIBRIUMIN IDEAL SYSTEMS
6G - ~ /~,6nl + ~ n,6,1 - ~ ,,dnl The term Z(1)n• Gibbs-Duhem An
(2.9.1)
vanishes at constant T and P by virtue of the
relation. important
displacements
constraint
-
in
carrying
O.
This
nfinitesimal,
virtual
to accord with the chemical reaction
can
virtual
be
guaranteed
by
(which also implies
introducing
6A, of the chemical
that the change
in mole number of every species
Then Eq.
(2.9.1)
an
"reversible")
of advancement, 6n i - vi6A.
out
is that the individual mole numbers n• must change
in proper synchronization wiAi
(T,P constant).
unit
reaction Z(1)viAi- 0, such i is given by
reads
6G - ~ ~i6nl - (~ wi~i)6A - (AGd)6A
(T,P constant),
(2.9.2a)
in which AGd "
(6r
~ v~#~[T.p.
(2.9.2b)
One must be very careful about the interpretation quantity
AGd:
differential reaction.
Gibbs This
advancement nearly
as indicated
preserves
calculated,
energy
accompanies
of the
participating
free
by the defining
reaction
the
in
number
the
change
an
per
of moles
T and
n i of
The
as shown in (2.9.2b),
unit
in
reversible
P, which
every
quantity
it is a
change
infinitesimal
at constant
reaction.
relation,
of the
very
species
AG d
may
i be
from the chemical potentials
#i prevailing in the reacting mixture during the infinitesimal, reversible reaction operating
advancement 2H z +
02 -
a fuel
cell
of
2HzO
the may
reaction. be
containing
carried nil2 moles
For
example,
the
out
reversibly
by
of H 2 gas
and no2
moles of 02 gas in appropriate compartments over the electrodes, and containing nil2o moles of water as the medium into which the electrodes is operated
are dipped reversibly
(see Section 4.6). by maintaining
As long as the cell
an appropriate
counter
emf, so that at the conclusion n~2 - 26A moles of H 2 gas and no2 -
6A moles of 02 gas remain in the compartments,
and nil2o + 26A
CHEMICALEQU~UBR~UM
239
moles of water are encountered, AGd(T,P)
directly.
a measurement of the emf yields
However,
if
the
reaction
is
allowed
to
proceed to the extent that vi6A becomes comparable to any of the above
n i's,
the
mole
numbers
are
no
longer
constant;
the
resulting Gibbs free energy change is then no longer identical with the quantity AG d in Eq. (2.9.2). detonation
of
calorimeter"
two moles
An extreme example is the
of H 2 and
one
mole
of 0 2 in a bomb
here the mole numbers are altered to the maximum
possible degree, T and P are no longer maintained constant, and the reaction is not carried through reversibly. Any measurement of the total free energy change AG for such a process will not even be
remotely
examples
should alert
when
different
reaction;
we
related
the reader
authors shall
to AG d as
refer
defined
to problems
to
a
consistently
free
use
earlier.
which may arise
energy
the
These
change
subscript
d
reminder of the differential nature of the quantity.
in
a
as
a
Equation
(2.9.2) shows clearly that AG d involves the chemical potential ~i for every
species participating
in the reaction under
the
prevailing steady c.ondltions which remain essentially unaltered in the virtual displacements.
Alternatively,
one may view AG d
as the change in Gibbs free energy when the reaction is carried out
such
that
6A equals
one mole
copy of the system under study. ~i can be determined one
need
not
in an essentially
Obviously,
is satisfactory
restrict
oneself
to
infinite
any method by which
for use in Eq. measurements
(2.9.2b);
carried
out
during the actual reaction. Equation
(2.9.2)
external constraints mole
number
values,
applies whether
the system
in a steady state condition in which the
n i remains
invariant
at
arbitrarily
or whether equilibrium prevails,
appropriate equilibrium values.
However,
with
be
taken
into
account;
we
thereby
the n i assuming
- 0 must
(6G/6A)T,e
obtain
condition characterizing chemical equilibrium,
(~ vi/~i),q- O.
prescribed
according to Section
1.16, in the latter instance the constraint also
is held by
an
important
namely,
(2.9.3)
240
2. EQUILIBRIUM IN IDEAL SYSTEMS
Note that if Z(i)l,,,i/,l i < 0 (> 0) the reaction as written will tend to occur spontaneously
(in the opposite direction).
(b) For an ideal homogeneous + RT s
Pi [see Eq.(2.4.15)],
gaseous system, # i -
#~P(T)
so that the equilibrium condition
(2.9.3) reads 0
- ~
,I~P(T) + RT (~i vl ~n Pi).q-
(2.9.4)
It is useful to rewrite Eq. (2.9.4) as follows" - ~ l,'i/i~tl(T)/RT Here
we
parametric
' p_.t. " ,In K, - ( ~ vl ,In Pi),q - ,In 'I' i F-] ~l,q(2.9.5a) have
function
of
T
that
alone,
characteristics
the
while
the
side
is a
right-hand
side
on
mixture.
It is therefore appropriate to introduce, a new quantity
left-hand
side
variables.
is
and
left-hand
depends (2.9.5a),
the
recognized
Kp which
actually
composition
shows
of
the
gas
as shown in
explicitly
independent
Kp is termed an equilibrium
of
that
the
composition
constant-
a highly
undesirable appellation because this quantity obviously varies with T. However,
the term "equilibrium constant"
is so firmly
entrenched that we shall continue to use it here.
A convenient
reformulation of (2.9.5a) Kp-
~
is found by taking antilogarithms:
(PVl).q. It is possible
Eq. (2.9.3). (2.4.17)] ~ i -
(2.9.5b) to provide
alternative
formulations
For an ideal gas one can set [see Eqs. ~c(T) + RT s
c i or ~ i -
for
(2.4.16),
~X(T, P) + RT s
xl, to
obtain 2n K c - - ~ ~C(T)/RT - (~ v i 2n cl).q
(2.9.6)
2n K x - - ~ v i ~ x(T,P)/RT - (~i v l 2n x i),q.
(2.9.7)
We
have thereby introduced two new
equilibrium
'constants,'
CHEMICAL EOUlUBRlUM
again
7.4 I
independent
of concentrations,
also being parametrically
dependent
the
one
(2.9.7)
on the total pressure
the system.
The problem of dimensionality
This matter
is briefly
discussed
in Eq.
later
of
arises once again:
and
fully
treated
in
Section 3.7(g). (c) The In the
evaluation
general
case,
of AG d is of considerable
when
equilibrium
mole numbers n i are arbitrary. advanced
infinitesimally
does
interest.
not prevail,
the
If the reaction Z(1)v• i - 0
and reversibly
at constant
is
T and P,
then under such condltlons -
§ RT
vl
Pi
298a
--
RT (~ v, ~n Pi).q + RT ~ v i ~n P,
(2.9.8b)
--
RT 2n Kp + RT ~ v• 2n Pi, I
(2.9.8c)
where
we have
inserted
Eq.
(2.9.5a)
on the right-hand
side.
Here and later on it is of the utmost importance to distinguish between Y~(1)vl 2n Pi, which merely from (E(1)vi 2n Pi).q, which at
this
evident
point
can
lead
has the same form as ~n Kp,
is identical with 2n Kp. Confusion to
disastrous
consequences.
that Kp and K c do depend on the units
pressures
and gas concentrations.
AGd/RT
independent
is
examlnation of Eq.
of
such
However,
choices,
as
It
chosen
is
for gas
the corresponding is
clear
from
an
(2.9.8b).
It is convenient
at this stage
to introduce
free e n e r g y change AG~ for the reaction.
This
a standard
is the value
of
AG d when the reaction is advanced infinitesimally and reversibly under
conditions
where
all
gaseous
constituents
are
at unit
partial pressure (usually one atmosphere) at the temperature of interest.
It may
not
be
possible
actually
reaction of interest under such conditions, not
detract
from
the
correctness
of
the
to
execute
the
but this fact does assertion.
The
definition is also consistent with the fact that we had earlier
4~
2. s
set AG d - Y.(t)vi~i; hence AG~ - Y.(1)ui~p.
IN IDs
Equation (2.9.5a)
SYSTs
thus
reduces to AG~ - - RT ~n Kp More generally,
Kp-
or Eq.
(2.9.8c)
exp(- AG~/RT).
(2.9.9)
reads (2.9.10)
AG d - AG~ + RT ~ v i ~n P i.
Note that the equilibrium constant Kp is directly related by Eq. (2.9.9) to the free energy change of a chemical reaction under standard conditions. under
Further,
arbitrary,
the AG d value
reversible,
for the reaction
isothermal,
and
isobaric
conditions may be written as a sum of AG~ and of a 'correction term' RT Z(1)vl 2n Pi. If
equilibrium
(2.9.10) AG~--
reduces
prevails,
AG d -
O;
in
this
(2.9.11a)
which is consistent with both remarks
made
quantity AG~ in Eqs. additional
(2.9.9) and (2.9.5).
earlier
(2.9.9),
requirement
concerning
(2.9.10),
AG d apply
and (2.9.11),
the
with the
advancement
at of
The definition (2.9.11b)
-
with ~
m ~p,
appropriate for
to
that all species must be maintained
their standard states during the infinitesimal the reaction.
Eq.
to
RT (~ v i 2n Pi).q,
The
event
the
gaseous
leaves no ambiguity" tables,
desired species
One measures,
or looks up in
the molar Gibbs free energy #~P (specified
standard
state,
usually
P-
i involved in the reaction.
I arm)
of
all
These quantities
are then to be combined as required by (2.9.11b). The
reader
the analogues
should have
of Eq.
(2.9.8c),
no difficulties namely
in constructing
2.4 3
CHEMICAL EQUlUBRlUM
AG d - - RT ~n K c + RT ~ v i ~n c i - AG~" + RT ~ v i ~n c i (2.9.12) AG a - - RT ~n K Z + RT ~ w i ~n x i It should be
clear
that
in these
again specified by (2.9.11b), or ~x.
Once more
confusion
between
corresponding
v i ~n xi.(2.9.13)
+ RT
equations
but now ~
AG~" and AG~" are
represents
either ~ c
the reader must be at great pains
to avoid
Z(t)v t
and
2n
ci
or
Ci)eq- 2n
(Z(t)u i 2n
Z(t ) u i
2n
K c or (Z(t)u i 2n
xt
Xi)eq-
the
2n K x.
The confusion easily arises because of the close similarity
of
the expressions. (d)
We
are
equilibrium pressure.
often
interested
~constant'
with
consider the definitions
variation
temperature
and
(2.9.5),
(2.9.6),
vl d - ~
R
[ - # ~ p]
aT
(2.9.14)
T
with
-
The cautionary
RT 2
applies
to
discussion
This
represents
the
total
(1.23.19)
and
Thus,
AH~ (2.9.14)
" RT 2"
is one formulation
(1886).
AH~"
~ wiH~
of
as well as (2.9.7).
(82n Kp/SP) T - (8~n Kc/SP) T - 0.
d~n Kp
Equation
the
We base our further discussion on Eq.
Obviously,
aT
in
of van't Hoff's
concerning the
equation
AG d and AG~ also
differential
enthalpy
evolution accompanying unit advancement of the reaction Z(1)v• i - 0 when the latter while
maintaining
standard
is changed reversibly
constant
states.
No
- Z(1)viH ~.
differentiation
of ~
partial molal T
under
methods
enthalpy
standard described
T and P, and all
ambiguity
definition AH~
and infinitesimally
results
species from
One should recall
in Eq.
(2.9.14)"
of species
conditions.
H~ thus represents be
the the
at temperature
determined
by
the
in Section 1.19.
One can reformulate the preceding results" and Pi - xIP,
of
that H~ arose by
i maintained
H~ may
use
in their
Since Pi - c•
244
2
2n K p -
2n Ko + ~ v i 2n R T -
EQUILIBRIUM IN IDEAL SYSTEMS
(2.9.15)
2n Kx + ~ v i 2n P.
Therefore,
d~n K o
d~n Kp
--
dT
d~n RT
AH~
~ vi
AH~ - RTAv
dT
RT 2
T
RT 2
-- ~ V i
dT
(2.9.16) W i t h AV IT,P - AvRT/P,
this becomes
(2.9.17)
d2n Kc/dT - AE~/RT 2 .
Finally,
(a2n K~/aT)p
and in v i e w of Eq.
(1.23.18),
(a2n Kx/aP) T - - ~ (vl/RT) i .
(2.9.18)
- d2n Kp/dT - AH~/RT 2,
'
- - (
v•
aP
~V~/Rr.
T
(2.9.19)
In p r a c t i c e Eq. (2.9.14) and its analogues are f r e q u e n t l y used
in
reverse.
d(#i/T)/dT
For
ideal
are identical;
gaseous
hence,
AH~-
mixtures
Alld - Z(1)viH•
Alld - RT 2 (d2n Kp/dT),
which
shows
empirically the
and so
(2.9.20)
if
the
variation
or from theoretical
gaseous
integration
2n
that
and
d(p~/T)/dT
reaction
~(1)viA i
of
analysis, -
0.
Kp
with
T
is
known
AH d may be found for
Note
further
that
by
of (2.9.20)
[K~(T2)/Kp(TI) ] -
~2
(AHd/RT2)dT,
(2.9.21)
T1 w h i c h requires
that one specify the d e p e n d e n c e
of All on T. Here
Kirchhoff's
law may be used if no other d e t a i l e d i n f o r m a t i o n
available.
Alternatively,
is
one may use the average value of AH d
CHEMICAL EOUILIBRIUM
- < A H a > , and move this constant outside
245
the integral to obtain
2n [Kp(T z)/Kp(T I) ] - (/R) (I/T I - I/Tz).
(2.9.22)
EXERCISES
2.9.1 (a) Prove that the quantities AG~, AH~, and AV~ refer not only to gases at unit pressure, but also to pure components. (b) Devise a semlpractlcal scheme for carrying out reactions in a fashion compatible with the maintenance of all gaseous components in their standard, pure states. (c) Carefully discuss the difference between AG~ - Z(1)vi~ i and AG m Z(1)nlu i -Z(1)nl, where ' and " refer to states before the start and after completion of the reaction Z(1)viA i - O. (d) O b t a i n relations among AG~, AG~', and AG~". 2.9.2 Consider the possible equilibrium n-C4H10(g ) iso-C4H10(g ) . The standard free energies of formation of normal and isobutane at 298 K are -3. 754 and -4. 296 kcal mol -I, respectively. (a) If we arbitrarily assign a value of zero to G ~ for the normal compound (G~ ) show that this means assigning a value o f - 5 4 2 cal tool-I to the iso compound (G~,o). (b) Assuming, first, that neither gas shows any tendency to convert to the other, find the free energy of a system c o n s i s t i n g of 0.800 tool of the iso and 0.400 tool of the normal in which the gases are unmixed, but each at a pressure of i atm. (c) Repeat (b) for the case in which the gases, both still supposed to be inert, are mixed at a total pressure of I atm. (d) Find the chemical potential of each gas in this mixture. (e) Suppose, now, that the isomers equilibrate readily. What w o u l d be the c o m p o s i t i o n of the equilibrium mixture? Would it depend on the total pressure? (f) What is the chemical potential of each gas in this equilibrium mixture? (g) What is the total free energy of the equilibrium mixture? 2.9.3 If Kp is 0.64 (atm) for N204(g ) - 2NO2(g ) at 318 K find the degree of dissociation under a total pressure of 2.0 arm. 2.9.4 For the reaction PCI3(g ) + Cl2(g ) _ PCls(g ), AG400o _ -855 cal. Determine the fractional conversion of PCI 3 to PCI 5 and the partial pressure of PCI 5 at 400 K, if the original reaction mixture contained I mol of PCI 3 and 3 mol of CI 2 and the total pressure is m a i n t a i n e d at I arm. 2.9.5 (a) Calculate Kp, Kc, and K x for the reaction 3H2(g) + N2(g) - 2NH3(g) at i000 K and under a total pressure of i00 O atm, given that AGd1000 - 61.890 kJ/mol. Starting with a pressure of i00 atm of NH3, what fraction decomposes into H z and
~-~6
2. EQUILIBRIUMIN IDEAL SYSTEMS
N 2 at I000 K under these circumstances? Repeat the above for the same reaction at 25~ given that A G ~ 2 9 8 - - 1 6 . 3 8 kJ. 2.9.6 For the reaction CO(g) + 2H2(g ) - C H a O H ( g ) one finds at 298.15 K (f represents the formation of compounds from their elements) ,,I
,
I,
,
, , ,
,
,
,
,,,,
,
,
,,,
,
,
AG~
s~
kcal/mol
kcal/mol
kcal/mol-deg
-26.4157
-32.8079
47.301
- 4 8 . I0
-38.70
56.8
,,,,
,,
,
,,
CO(g) CH3OH(g) **
H2(g)
31.208
(a) Determine AG~2~8, AH~298, ~ , Ko, and K x at 298.15 K. (b Taking XCH30H -- 0.8, Ptot - 1/2 aim, find XH2 , Xco at 298.15 K. (c) Derive a general expression for Kp in terms of the fraction of CO consumed, starting with n moles of CO and m moles of H 2. 2.9.7 Let n~ represent the number of moles of species i present in a system which is allowed to interact chemically so that the degree of advancement is A. Find n and x i in terms of n~, A, a n d Av - ~v i. 2 . 9 . 8 At 2 ~ . 5 ~ a n d a p r e s s u r e o f 5 8 . 7 ram, t h e d e g r e e o f dissociation o f N204 i s 0 . 4 8 3 . F i n d K= a n d Kp. Calculate the volume occupied by i (original) tool of N204. At what pressure will the degree of dissociation be 0.i? 2.9.9 A mixture containing 49~ of HCI and 51 ~ of 02 by volume was heated at a constant pressure of 723 nun to 480~ At equilibrium 76~ of the HCI had been transformed according to the equation 4HCI(g) + O2(g) - 2 C 1 2 ( g ) +2H20(g). Find the values of K c and Kp (pressures in atmospheres). 2.9.10 A certain ideal gas, A, isomerizes to B, according to the reaction A - B and forms an ideal gas mixture with equilibrium constant Kp. Starting with i mol of pure A at I atm, the gas is allowed to isomerize at constant temperature and pressure until it reaches equilibrium. The isomers are then separated and each is brought to i atm at constant temperature. Find AG d for the process. Show that AG d is not equal to AG~. Explain. HCI(g), C ~ - 6.7319 + 0.4325(I0-3)T + 3.697(I0-7)T 2 02(g), -C~- 6.0954 + 2.2533(I0-3)T- 10.171 (10-7)T 2 H2(g), C~ - 7.219 + 2,374(I0-3)T + 2.67(I0-7)T 2 Cl2(g) , C ~ - 7.5755 + 2.4244(I0-3)T- 9.650(I0-7)T 2 Find Kp at 500~ and AG~500. 2.9.11 (a) The following table gives the standard Gibbs free energy of formation of Cl(g) at several temperatures. T(K) i00 I000 300 AG ~ (kcal/mole CI) 27.531 15.547 -13.487.
CHEMICALEOUlUBRlUM
247
For the reaction (i/2)C12(g) - e l ( g ) , find the e q u i l i b r i u m constant Kp at each of these temperatures. Find the mean AH~ and then find AS~ per unit reaction at each of the temperatures. (b) At 1700~ and i.i0 atm, i g of chlorine occupies 1.96 liters. What are Kp , K x, K c for the reaction (1/2) Cl2(g) - C l ( g ) ? Assume ideal-gas behavior. (c) At 1600 K, the degree of dissociation of chlorine is 0.071 at i atm. What are Kp, Kx, and Kr for the reaction Cl2(g) - 2Cl(g)? Assume ideal-gas behavior. 2.9.12 (a) At 448~ the degree of d i s s o c i a t i o n of HI into H 2 and 12 is found to be 0.2198. Determine Kx, Kc, and Kp. (b) If 0.05 tool of H 2 and 0.01 of 12 are brought in contact at that temperature in a volume of 3 liters, what c o n c e n t r a t i o n of HI is produced? (c) At 357~ K c - 0.01494; if 0.04 mol of HI, 0.03 tool of 12, and 0.02 tool of H 2 are e q u i l i b r a t e d at that temperature in a volume of 3 liters, calculate the c o m p o s i t i o n of the e q u i l i b r i u m mixture in terms of mole fractions, molaritles, and partial pressures. 2.9.13 Let K 1 and K 2 be the e q u i l i b r i u m constants at a temperature T for the reactions 2CO 2 - 2CO + 02 and 2H20 - 2H 2 + 02, respectively. Find K 3 at temperature T for the reaction H 2 + CO 2 - H20 + CO in terms of K I and K 2. 2.9.14 For the reaction 2SO3(g ) - 2SO2(g ) + 02(g ) one finds values of K c - 3.15 x 10 -4 , 3.54 x 10 -3 , and 2.80 x 10 -2 P llter -I at 627, 727, and 832~ respectively. (a) Determine the average enthalpy of reaction under standard conditions in the intervals 627-727~ and 727-832~ (b) Determine K c and Kp at 500, 700, and 1000~ (c) What fraction of SO 3 is d i s s o c i a t e d at these temperatures if the total pressure is 2 a t m in each case? (d) A s s u m i n g air to consist of 79% N 2 and 21% 02 by volume, what percentage of SO 2 is transformed into SO 3 if equal volumes of SO 2 and air are mixed at 727~ at a total pressure of 1 arm? 2.9.15 (a) Derive an expression showing how AS values for a chemical reaction carried out at temperature T I may be related to AS for the same reaction at a different temperature T 2. (b) For the reaction H2(g) + Cl2(g ) - 2HCl(g), the standard entropies at 298 K are 31.208, 53.288, and 44.646 eu/mol for H2(g) , Cl2(g) , and HCI(g), respectively. Also, C ~ - 6.9409 - 1.999 x 10-4T + 4.808 x 10-TT 2 cal/deg-mole (H2) C ~ - 7.5755 + 2.4244 x 1 0 - 3 T - 9.650 x 10-7T 2 cal/deg-mole (C12) ~ 0 _ 6.7319 + 0.4325 x 10-3T + 3.697 x 10-TT 2 cal/deg-mole (HCI) Calculate AS~ at 298 and 1200 K for these reactions. 2.9.16 (a) Find K for H2(g ) + 12(g ) - 2Hl(g); AG~98 = - 4 . 0 1 kcal. (b) Find Kp for 2Hl(g) - H2(g) + 12(g ). (c) Find Kp for (I/2)H2(g) + (1/2) 1 2 ( g ) HI(g). (d) For H2(g) + 12(g) O 2Hl(g), Kp - 870 at 298 K and AHd2s8 - -2.48 kcal. Find Kp at 328 K, assuming AH d is constant in this temperature range.
~-48
2. EQUILIBRIUMIN IDEAL SYSTEMS
2.10
CHEMICAL EQUILIBRIUM
(a)
The
methodology
of
applied
to homogeneous
phases.
Here Eq.
IN HOMOGENEOUS
IDEAL SOLUTIONS
the
preceding
section
ideal
solutions
which
(2.5.1) is applicable,
now
be
condensed
~I(T,P) - ~ ( T , P )
In xl, where ~i is the chemical potential value obtained when x i - x~ - i.
will
form
+ RT
of pure i, i.e.,
the
The equilibrium condition now
reads
0-
(
vi~i).q-
Again,
vi~i(T,P) + RT (
v i ~n xl).q.
(2.1o.i)
it is convenient to define an equilibrium
'constant'
as
follows"
2n K . - -
~ vllm~(T,P)/RT- (~ w,
This
the
has
same
form
as
Eq.
In x,).q. (2.9.5a)
(2.10.2) except
that
present case K Z depends parametrically on T and P.
in
the
Accordingly,
by the method of Section 2.9,
(a2n
K./aT)p -
vIHI(T,P)/RT 2 - AH$/RT 2
(a~n K./aP)T - -
vIVI(T,P)/RT - - AV$/RT,
and, by analogy with Eqs.
AG d - -
(2.10.3) (2.20.4)
(2.9.8),
RT 2n K x + RT ~ v i 2n x i
(2.10.5a)
- AG~* + RT ~ w i 2n x i. (b)
Since
frequently
(2.10.5b)
equilibrium
expressed
molallty
m i or
relation
between
constants
in terms
molarity xl,
ml,
cl,
in
of c o n c e n t r a t i o n it
and
is c i.
necessary From
the
solutions units to
are
such as
examine
definition
the of
molarlty and mole fraction we obtain
cl/x i - (nl/VL) (~nj/nl),
v L - V/lO00,
(2.10.6)
249
HOMOGENEOUS IDEAL SOLUTIONS
where
V
is
quantity ms/p,
the
volume
is related
and the mass
of
the
solution
to the density of the
solution
in
cm 3.
p of the
The
latter
solution
by V -
is given by m s - Y.(j)njMj,
where Mj is the gram atomic mass of constituent
J.
Thus,
i0009(i + n~/nz + ns/nz +...) ci/x i - I0000~ nj/~ njMj -
M I + (n2/nz)M2 + (na/nz)M3 +... (2.10.7)
Consider
now the case of a dilute
sensibly
expect
designate
the
near-ideal solvent.
niMi/n I
I
PRaoult's
i 'as'e~ 'on
.--2>> i implies that AG~ is a large negative quantity, equilibrium
the
specification
of K or Kq causes no difficulty It
(3.7.12),
evaluated
the
AG d is
fundamental
and as
of choice adopted for Kq
in
reference
state functions the
arbitrariness
units
matched
the composition
thermodynamic AHd)
It
to be
the vagaries
exactly
standard
specifying
or
Thus,
ql are
activity coefficients,
(3.7.12).
changes
71 and
(3.7.9c)
the pertinent
Thus,
reaction
has proceeded nearly to completion in the direction as written. Conversely, when
the
for values reaction
direction.
Thus,
is
of K or Kq /aP]t,.,, i -
where
ai(X)/SP]T,.i
[82n
use
[a,en a~m>/aP]t..,, i I
I
was
made
of
-
Vi/RT
differentiation
Section
3.7(a),
whereas
V i - Vi(T,I ).
Eq.
(3.5.15)
as
(3.4.5)
discussed
with
q -
c
in
and
xl
Vl/RT - V~/RT -
[a~n p/OP]T,x~ (3.10.2)
pi(T,P)/OP]T,xl,
also used Eq.
[a~n Fi(m)/aT]p,ml ffi ffi [ 0 2 n
and
P:
[a,~n a~C>/aP]T,ci - [O,~n a[X)/aP]T,xi
[a~n P/OP]T,~t -
+ lira P~l [a2n
to
Here one must be very careful
V i - Vt(T,P), to
v i to
is r e f e r r e d
to
we find at constant
where we have
(a#i/aP)T,xl-
respect
[a~n r'~o>/aP]:r.ci -
-
of
with
According (3.4.2),
and
note that #i(T,P,x•
the standard chemical potential. the
(3.1o.t)
V~/RT,
(3.5.12a)
arrive at the final result; in
-
[a.~n r~*>/aP].t..i
(3.10.1).
Similarly,
we find
[a~n ai(m)/0T]p,mt- [as r[=>/aT]p,~i
at(X)/0T]p,xi
-
-
(H i -
Hi)/RT 2
(3.10.3)
[a2n r~=>/aT]p.= i ffi [a2n a~=>/aT]p,= i ffi [a2n a~X>/aT]p,xi +
[a2n
(pt/p)/@T]p,x i
---
(H i - H i ) / R T 2
+
[0s
(pl/p)/OT]p,x i.
(3.10.4) Note
here
enthalpy from
that
of pure
~i(T,P,xl) ,
solution
Hi,
derived
i at unit refer
at pressure
P.
to
from
pressure, the
pi(T,l,xl), while
partial
is
the
molar
Vi and Hi, d e r i v e d
molar
quantities
in
3 2.4
3. CHARACTERIZATION OF NONIDEAL SYSTEMS
(b) The variation of the different equilibrium constants with
temperature
Since Kx(T), in Eq.
and
pressure
as determined
(3.7.8a),
Eq. (3.7.6a),
may be
determined
as
follows:
in terms of the chemical potentials
is identical to K(T) as specified by the ~
in
these two quantities may be considered as a unit.
One obtains d~n K(T)
d~n Kx(T ) u
dT
- ~ v,H, x~, one reverts back to a single phase,
and PI again varies with x I until
the value
is
liquid
PI - PI is
reached for x I - i. Note merge
with
further the
that as x I ~ i, all curves
one
for
which
B-
O;
this
in Fig. agrees
3.13.3
with
the
experimental fact that Raoult's Law always holds in this range. Similarly,
as
xI ~
0
consistent with Henry's with
each
solution.
one
obtains
Law; For
Raoult's Law are encountered,
here B
0
line
region
as x I ~ 0 varies deviations
from
one finds positive
354
3. CHARACTERIZATION OF NONIDEAL SYSTEMS
deviations positive
with
slopes
departure
Finally,
that
become
steeper,
we
should
note
that
in
terms
R(x I ~n x I + x 2 ~n x2) represent
which,
in the present approximation
an ideal solution. AH-
AG + TAS.
the
B
We may rewrite
w/RT
-
definitions
greater
the
Eq.
(3.13.13)
the entropy
scheme,
the
of mixing,
is the same as for
The term Bxlx 2 is then to be identified with
AG m - RT{X 1 ~n x I + x 2 ~n xz} in w h i c h
the
from ideallty.
and AH
for
mole
Eq.
(3.13.13)
as
(3.13.17)
+ wxlxz, - RTBxlx 2 - wxlx 2.
fraction
we f i n d
On introducing
[AG -
nAG -
(n 1 +
na)nC] (3.13.18)
AG m - RT(n I ~n x I + n 2 ~n x2) + w(nlnz/n ).
It is quite remarkable how many firm deductions are b a s e d on
a
single
formulation the
hypothesis.
(3.13.12)
specification
mixing phase
functions separation
fn equilibrium value
of
critical
B
in
Fig.
predicted.
of
AGm,
does occur
composition
of
Finally,
The
shown
in
by
by
Eq.
incipient the
foregoing
power of thermodynamic
is
leads directly
to
other
(3.13.3)-(3.13.7).
When
of the two phases
(3.13.14). phase
mixture
deviations
Margules All
one may construct which
the
(3.13.13).
the c o m p o s i t i o n
specified for
3.13.3
as
are then found from
is
with
for rl, thermodynamics
required
(3.13.15c).
Beginning
are
a beautiful
critical
separation
and
the
specified
by
Eq.
diagrams from
The
such as shown
Raoult's
illustration
Law
are
of
the
methodology.
EXERCISES 3.13.1 Sketch out derivations by which AG m and other mixing functions may be specified in terms of 71(T,p,cl) and 71 (T, P ,ml). 3.13.2 (a) Derive Eq. (3.13.11) and (3.13.12) in detail, proving that D I - D 2 - 0 and B I - B 2 R B as stated in the text. (b) Expand on the derivation by adding terms in x 3 and x 4 to Eqs. (3.13.9). Obtain expanded relations for ~n Vl and AG m.
MIXING IN NONIDEALSOLUTIONS
3~5
3.13.3 (a) Starting with Eq. (3.13.13) derive ex~resslons for ASm/RT, ~/RT, AVm/RT , AEm/RT , (ACp) m/RT , (ACv)m/RT on the assumption that B depends on T via B - w/RT, w being constant. (b) Make sketches showing the dependence of each of these on x z - x for B - - i , 0, 1.5, 3, at T - 300 K. (c) Comment on the nature of each of the curves. 3.13.4 (a) Determine the Henry' s Law constant in terms of B for a binary solution to which Eq. (3.13.13) applies. (b) Discuss negative departures from Raoult's Law in terms of Eq. (3.13.13). 3.13.5 The normal isotopic abundances for Li are 92.48 mole % for 7Li and 7.52 mole % for SLi. Making reasonable approximations, determine the entropy, enthalpy, and Gibbs free energy changes on mixing the pure isotopes. Discuss your results in terms of the statements made in Section 1.21 in conjunction with the Third Law of Thermodynamics. 3.13.6 For some kinds of high-polymer solutlons, the chemical potentials of solvent and solute are given by the approximate equations
~I - G~(T,P) + RT {2n 41 + (I - ~ )
2n (I - 41)[ + w(l - 41) 2, G z - G~(T,P) + RT {2n 42 - (r - I) 2n (I - 4z)'} + rw(l - 42) 2,
where r stands for the degree of polymerization and 41, for the volume fractions 41 - NI/(NI + rN2) 4 z - rNz/(NI + rNz). Here N I and N 2 are the number of solvent molecules and of solute high-polymer molecules, respectively. It is assumed that each polymer molecule consists of r monomers, and that the volume of a monomer approximately equals the volume of a solvent molecule. (a) Determine ~I and ~z in terms of x I and xz, and x I and x 2 in terms of 41 and 42. (b) Compare the entropy of mixing of this solution with that of an ideal solution. (c) Derive the relation of the enthalpy of mixing to the concentration of this solution. 3.13.7 The following expression has been proposed for the activity coefficient of component 1 in a two component solution" ~n F 1 = AV~422/RT, where V I is the molar volume of pure i, at temperature T and total pressure P, and A is a constant. The volume fraction 42 is given by 42 " n2V2/[ nlVl + n2V2 ] 9 On the basis of elementary theories one finds that A - [ (A~ap)i/V~] I12 - [ (A~ap) 2/V2 ]-* 1/2. (a)
Derive
a relation
for
2n F 2.
(b)
Prove that
the
free
energy
of mixing is given by AG m - RT[n I 2n x I + n 2 2n x2] + A(nlV I + n2Vz)4142. (c) Let the second term on the right of the expression for AG m be the excess free energy of mixing G.. Obtain expressions for
56
3. CHARACTERIZATION OF NONIDEAL SYSTEMS
S., H., V.; the final relations
should include the functions
=~- (~i)-~(a~'~/aT)p; ~ . -
(~'~)-~(a~'~/aP)~.
(d) Simplify the expressions in (c) by n e g l e c t i n g terms in (@I ~2)(=I - =2) and (~i - ~2)(~I - ~2)- Provide arguments to show why these quantities should be small. 3.13.8 It is found empirically that, for many systems, the equilibrium vapor pressure of component 2 in a nonldeal solution is given by P2 - (2x z - x~)P~. (a) Obtain an expression for 72 relative to the solvent standard state for component i and determine V2 at x 2 - 1/2. (b) Obtain an analytic expression for PI in terms of x I. (r Does one obtain positive or negative deviations from Raoult's Law? For what range is dPT/dx 2 > O? For what value of x 2 is a m a x i m u m e n c o u n t e r e d in PT, the total pressure in the system? 3.13.9 Let the ~unsymmetrlcal' Gibbs free energy of a mixture be given by the expression G - nl#~ + n2# ~ + RTIn I 2n (nl/(n I + rn2))l + RTIn 2 ~n (rn2/(~ I + rn2)) 1 + Bnln 2, where B - B(T,P), ~ #~(T,P). (a)'Obtaln the relation for the molar Gibbs free energy of the mixture solely in terms of mole fractions. (b) Obtain S, H, V, E, Cp, and C v in terms of xl, x 2 and parameters. (c) Determine the vapor pressures PI and_P2 in terms of a modified Raoult's Law. (d) Plot AS~/R, A H ~ R T , AGm/RT, P2 as functions of x 2 for r 1/2, 2, 1/5, 5; assume constant T and P. Here AG m refers to the molar free energy of mixing. Comment on the nature of the curves you obtain. 3.13.10 For the acetone-carbon disulfide system the following activities have been reported at 35.17~ (subscript 2 refers to CS2) -
X2
6.24 x 10 -2 0.1330 0.2761 0.4533 0.6161 0.828 0.935 0.9692
a2
0.216 0.405 0.631 0.770 0.835 0.908 0.960 0.970
al
0.963 0.896 0.800 0.720 0.656 0.524 0.318 0.1803
Determine AGm, AHm, TAS m for the system and plot the results. Do you detect any evidence for phase separation? 3.13.11 Let the excess molar and partial molal Gibbs free energy for a two-component mixture relative to an ideal mixture be given by AG I - x2[A - BT + C(x 2 - x I)], AG - xlx 2(A - B T _ + Cx2) , in which A, B, and C are constants. Determine H, S, G2, HI, H2, $I, S 2 for this system. 3.13.12 The following type of equation is frequently used in the empirical representation of data in a binary solution"
PHASESTABILITY
3 ~7
~n V l - AI(T)x~ + BI(T)x~ + CI(T)x~ + DI(T)x s, _where_ A I through D I are independent of composition. Determine AOm, / ~ , and AS m for the binary solution from this relation. 3.13.13 The heats of mixing have been reported for various solutions of carbon tetrachloride and acetonitrile at 45~ as summarized below: XccI 0. 128 0. 317 0. 407 0.419 0. 631 0. 821 AH(s4olen) 99 179 206 235 222 176 cal/mol solution (a) Using these data and the tabulations in Exercise 3.11.14, determine AHm, AGm, TAS m for Xcc14_- 0.I, 0.2, ...,0.9, and plot the results. (b) Assuming that AS m may be approximated by the relation that applies to an ideal solution, use these data to calculate the activity coefficients of CCI 4 at x - 0 . 1 2 8 , 0.317, 0.419, and 0.631, and compare these wlth the values that are interpolated from Exercise 3.11.14.
3.14
(a)
PHASE STABILITY" FROM IDEALITY We
had
earlier
GENERAL CONSEQUENCES OF DEVIATIONS
encountered
specific
examples
deviations
from ideal behavior of binary solutions
phenomenon
of
phase
separation.
We
now
where
led to the
introduce
several
generalizations on the basis of qualitative sketches introduced later. In
ideal
solutions
the
mixing
process
is
rendered
spontaneous through the positive entropy of mixing A S / R - ~ n x I + x 2 ~n x 2
I > 0; here AH- - 0.
{xI
The molar free energy for
ideal solutions reads
G -- RT
x I 2n x I + x 2 2n x 2
__
(3.14. la)
+ (x1# ~ + x2#2)
(3.14.1b)
T A S 0 + G*.
Qualitatively,
Eq. (3.14.1) may be represented as shown in Fig.
3.14.1(b), where energy is plotted schematically versus x 2 m x. The plot shows - TAS0 versus x as the bottom curve; the sloping baseline
(top curve)
x2~ 2 in which ~i and shown in the
middle,
for G* is obtained are held constant. ~ z
- T A S 0 + G',
from the sum Xl~ I
+
The resultant graph, is a
skewed
U shaped
.58
3. CHARACTERIZATION OF NONIDEAL SYSTEMS
A~
o[
o
0
A~ -TAS
0
•
0
1
•
(a)
1
0
x2
(b)
FIGURE 3.14.1 Free energies G of b i n a r y solutions. (b) AH = 0,
curve. (i)
exists
solutions
in general
there
an
expression
AS--x
parameter.
One
in Figs.
I ~n x I + x 2 ~n now obtains
3.14.1,
given term
by of
AH
= wx(l
Eq.
- xr);
(3.13.17)
(rx2) , w h e r e
(a) and
but
two
entropy
TAS
(c).
this r
term Se that
relation =
I.
r is a s u i t a b l e
curve
of
the
type
(ii) The e n t h a l p y
is a f u n c t i o n
when
corrections"
sum may be s i m u l a t e d by the
a skewed-
parts
m i x i n g no longer v a n i s h e s
occur
excess
must be a d d e d to ASo, the r e s u l t i n g
shown
(a) AH < 0,
(c) AH > 0.
For n o n i d e a l
There
1
(c)
of x 2 n x,
reduces On
to
such as the
introducing
corrections
one obtains a new curve as in part
and in part
(c) where w > 0.
The r e s u l t a n t s
of
last these
(a) w h e r e w < 0,
o b t a i n e d on a d d i n g
up the s l o p i n g baselines,
the entropy,
and the e n t h a l p y c o n t r i -
butions
the curve
In part
more
are
i n d i c a t e d by
negative
and more
(c) a n o n m o n o t o n i c
variation
over c e r t a i n ranges the n e g a t i v e shown
skewed
such
than
for part
a
(a) G is s i m p l y but
in part
of G w i t h x is obtained,
because
of x the large p o s i t i v e
contributions
shortly,
G.
associated
situation
(b),
All v a l u e s
with-
signals
the
TAS.
outweigh
As will
onset
of
be
phase
separation.
(b) In this c o n n e c t i o n
it is of some
h o w much of each phase must be p r e s e n t
interest
to e s t a b l i s h
to form a h e t e r o g e n e o u s
PHASE STABILITY mixture Table
359 of
average
3.16.1,
Consider i -
fraction that
the
second
mole
n~(n A +nB)
377,
fraction
x.
in d e r i v i n g
nA + n B moles
x m nA/n.
phase
numbers
p. n-
mole
Let
fraction
A
in
i - x"
, respectively.
in the " p h a s e
Eqs.
reader
Let
first
- n~/(n~
be 1 - f -
t h a t n A - n ( l - x), of
substituting
and
f -
(x-
I - f -
which
x')/(x"
(c) a given
+ nB)
fraction
If
the
numbers
solving
for
the
1 - x" -
total mole
Then
one
requires f one
and nA - nf(l
that
nA -
nA +
finds - x"). n A.
On
obtains
- x'),
as
(3.14.2b)
the L e v e r
Rule.
set of c o n d i t i o n s ,
x o for a s y s t e m were
in
such
(3.14.2a)
is h o m o g e n e o u s
alloy
and by
- x')
For a given
mole fraction
and
o f the
(nA + nB)/n.
n A - n ( l - f ) ( l - x'),
are k n o w n
alloy
formed
mole
N
mole
(x" - x ) / ( x "
results
be
phase
#
Conservation
consult
an overall
mixture
the
the
may
(3.14.2).
of A and B with
a two-phase
of
is g i v e n b y
The
simply
or
c a n one p r e d i c t
not?
Consider
for w h i c h
Fig.
a mechanical
a
3.14.2
whether
solution
of
is r e l e v a n t .
mixture
of
the p u r e
2~ r c u.l
GA
0
• X~X
2
FIGURE 3 . 1 4 . 2 D i a g r a m o f G v s . x , s h o w i n g how t h e h o m o g e n e o u s phase has a lower free energy than any biphasic mixture.
360
3. CHARACTERIZATION OF NONIDEAL SYSTEMS
components
A and B, then according to the Lever Rule
the free
energy of the system would be given by the intersection of the straight llne joining G A to G B with the vertlcal line at x - x o, labeled G* in the diagram. If instead the phase mixture involved two
solutions
of compositions
x a and xa,
then
the
same
Lever
Rule yields the free energy of the alloy designated as G a. Since Ga < ~* p
this new state
Analogous
remarks
is more
apply
stable
to another
than the orlginal
heterogeneous
one
9
alloy whose
two compositions are represented by x~ and xb; the corresponding free energy,
~,
is still lower.
Continuing this process
it is
found that at the composition x where the two phases merge into a slngle homogeneous solutlon of composition Xo, the free energy attains
its
lowest
configuration. 3.14.2,
For the type
value, of free
82G/ax 2 > 0 for all x; hence,
two points
on the
these points. U-shaped
possible
curve
always
lies
G O . This energy
is
the
displayed
stable in Fig.
any straight llne joining above
the
curve
between
When the free energy versus composition curve is
the homogeneous
solution
always
has
the
lowest
free
energy. By contrast, of
composition
curve G in Fig.
consider as
the free energy curve
sketched
3.14.1(c).
in Fig.
3.14.3,
as a function
which
reproduces
If an alloy of composition x o were
I
I
I I I
0
x'
I I 1
Xo
x"
1
X
FIGURE 3.14.3 Diagram of g versus x, illustrating a condition in which a biphasic mixture of relative composition x" and x" with respect to the second component is the most stable configuration for a solution; here x" _< x _< x". For O _< x < x " and for x" < x _< I, a homogeneous phase is stable.
PHASESTABILITY
to exist
36 I
as a
homogeneous
solution,
its
be given by the point G O on the diagram.
free energy would
On the other hand,
if
9
N
the alloy were a heterogeneous mixture of composition x a and x a for component 2, the free energy of the system would be lowered to G a.
By choosing x" and x" to be more widely
composition minimal
one progresslvely
value
G
is
lowers
reached
separated
in
the free energy until
when
the
two
phases
are
a of
composition x" and x"; here the straight line forms a tangent to the two curves near the local minima.
Any attempt to spread
the composition of the two phases further will lead to a rise N
in
free
energy,
as
is
illustrated
for
xb
and
x b,
with
a
is
thus
a
corresponding value for C~. The
stable
heterogeneous x",
state
of
mixture
the
system
under
study
of composition x" and x".
For x" < x
x n only Thus,
in the
heterogeneous region the compositions of the two phases of the mechanical mixture remain constant, but the relative amounts of material
in each phase changes with alterations
in x.
(e) The presentation may readily be generalized to a system
36~-
3. CHARACTERIZATION OF NONIDEAL SYSTEMS
Comp.B
Comp. A
1-f
X'
X" x~ x B
FIGURE 3.14.4 V a r i a t i o n of the makeup of a b i n a r y system w i t h relative c o m p o s i t i o n (mole fraction), shown as a plot of I - f and of f versus x.
in which
more
shown i n F i g .
than
two
3.14.5;
phases
here
appear.
A
typical
t h e homogeneous
example
is
and h e t e r o g e n e o u s
c o m p o s i t i o n ranges are delineated by use of an imaginary string B'
/ A~
I
T+5 i;r
P
i
B+T
l I I I
O x
FIGURE 3 . 1 4 . 5
Gibbs
free
energy
as a function
mixtures of intermediates are formed. indicated
by
cross-hatching
on the
of x when several
Stable single phases are
x scale.
PHASESTABILITY
363
that is tightly wound around the curves between points A' and B"
in
the
diagram
constructions.
to It
exhibit is
all
possible
customary
to
.common
tangent
designate
phases
consecutively by Greek lowercase letters in alphabetical order. The various phases and their composition ranges are indicated on the diagram.
In general,
if AH is small, as is likely to be
the case for homogeneous solutions, a
function
of
composition ranges
curve,
and
the
phases
are
stable
formed,
deviations
remain very small. the from
free the
energy
as
of
are
forms
compound
does
broad, over
However,
from the appropriate
shallow which
when
a
U-shaped
the
single
compound
stoichiometric
is
ratio
This is reflected in the very sharp rise of the composition
depicted in Fig. 3.14.6; over
a
composition
large.
stoichiometric ratio.
is stable
the free energy plotted as
not
even
slightly
A situation of this type is
it is seen that the composition x - x i
only a narrow
stoichiometric value;
is changed
range.
necessarily for example,
The composition
coincide
with
of the
an
ideal
the compound CuAI 2 does not
/
7"
J
+
~YAx
0
x
1
FIGURE 3.14.6 Gibbs free energy as a function of mole fraction for a binary mixture involving formation of a compound corresponding to the phase with stoichiometry Ai_xiBxl. Crosshatched composition ranges indicate stable monophasic regions.
364
3. CHARACTERIZATION OF NONIDEAL SYSTEMS
exist,
but
a compound
on the Al-rich
side
of this value
is
stable.
EXERCISES
3.14.1 Discuss in terms of chemical potentials why phase equilibrium requires the tangent constructions described in this section. 3.14.2 Prove that the common tangent construction is equivalent to the equality of chemical potentials of the phases whose compositions are given by the points of tangency.
3.15 The
DISCUSSION OF SEVERAL TYPES OF PHASE DIAGRAMS general
correlated
features with
of standard phase
the
free
3.14.
For
simplicity
where
the
liquid
energy
we
curves
immediately
phase
is
diagrams
will now be
depicted
in
Section
specialize
to
systems
homogeneous
throughout
its
composition range; the corresponding free energy curve is then U-shaped,
as depicted
in Fig.
3.14.2.
In our
first
example,
Fig. 3.15.1, the solid state also exists only as a homogeneous solution.
Quite generally,
as the temperature
is lowered the
free energy curve of the solid moves past that of the liquid, and
the
shapes)
shape
of
will
also
each be
curve
(i.e.,
altered.
the
skewness
Thus,
with
of
the
U
diminishing
temperature the two free energy curves will intersect and give rise
to
situations
where
the
common
tangent
indicates the existence of biphasic mixtures. the temperature energy
curve
T I is sufficiently high
for the
liquid,
Gi(x),
construction
In Fig. 3.15.1a
that the entire
lies below
that
for
free the
solid, Gs(x) ; at any composition x, the system is stable in the liquid state.
As the temperature is lowered to a value T A (part
(b)), the two free energy curves touch at the composition x 0; solid and liquid now coexist for the pure phase, the melting
point
of pure
A.
However,
for x >
and T A is
0 the
free
energy of the liquid remains below that of the solid. As T is reduced further to the value T 2 (part (c)), the GI(x) and Gs(x )
TYPESOF PHASED I A G R A M S
36S
(a)
T~
(b)
TA
(c)
I
T2
I
t
B
A
XB
X B -----~.-
(d)
{(e)
TB
XB,L-~
IA(I.f). . . . § . . . . . . . . . . . . .I". . ! .... t ..... ! ......... TA
T3
I
xh
r2
Liquid Solid
I A
B
x B-~,.-
B
A XB
x s or
intersect, xs
T^ > T 2 > T B > T 3.
such that in the composition
is stable;
""\
X B ~
FIGURE 3.15.1 D e r i v a t i o n of a phase curves of liquid and solid phases. curves
1,,/
A
~
0 _< x
0 for this case,
less
stable
than
the solid s o l u t i o n
a mixture
of phases;
indicated by the dotted curve at the b o t t o m
TA
(a)
i
Te,
this
is
of the diagram.
.
T1
(b)
(c)
s
I
I ~+i
b;~i XB ~
B (d)
A a I
s
t
b
XB---~ T3
B (e)
A
TA a .,~
I
~
J.. Y
L
d Xa-~ L
'
IL+s e
1 f
s
B (f) l
TB t I-1
.........
~ E ~
I
XB
c
b_....................
y
A
1L+s
T2
T~ //" A + B \\\
B
A
XB
B
A
T
X B ..______ ~
I B
FIGURE 3.15.2 D e r i v a t i o n of a phase diagram with a minimum, obtained from free energy curves of liquid and solid phases. TA > T B > T 1 > T z > T 3 > T c .
TYPES OF PHASE DIAGRAMS
36 7
SolMd Md Sol
lquld
/
To
(o)
(e) (b)
To
Tc
E
(d) Liqu,d
I
~ Tc
I Td I
5O
o A
100 B
Mole Percent B 0 A
I B XB~
FIGURE 3.15.3 Gibbs free energy curves for liquid and solid mixtures which result in a phase diagram with a maximum.
A second case which no
frequently
the components
intermediate
encountered
are only p a r t i a l l y miscible
phases
are
curves are shown in Fig.
formed.
3.15.4.
somewhat curves
composition
below
range.
the melting
for solid
liquid phase
of pure
intersect,
By the common tangent construction, the h o m o g e n e o u s
relevant
A,
free
energy
T - T I, G t (x) is stable over
At a p a r t i c u l a r
point
and liquid
The
a solid for and in w h i c h
At temperature
< Gs(x ) for all x; the homogeneous the entire
involves
value
the
as shown
free
T - T 2, energy
in part
(b).
we see that for 0 < x < x"
solid alloy is stable;
for x" < x < x" solid of
c o m p o s i t i o n x" is in equilibrium with liquid of c o m p o s i t i o n x"; for x > x" the homogeneous
liquid phase is stable.
Part (c) is
typical of a temperature T 3 at which G, and G e intersect both at the
A-rich
homogeneous x
N
Electrostatic gradient
Electr,c field
Ct > Cr
~-~-r
-G
--
~r
~r > ~I, ' •r >121,
~Cp ~
potential
Cui r e w
~'L > ~r
1
r
+
Elect rode A
wire Cu
Elect r o d e C
FIGURE 4.6.2 Schematic diagram illustrating the directions of electric field, electrostatic potential gradients, electrochemical potential gradient, and emf for a representative cell under open circuit conditions, and set up in accord with Conventions i and 2, developed later.
- RT d~n a 9_ potential
VF~, points -"
to the left and the electrochemical
itself is governed by the inequality ~e_(2) > ~e_(r).
We now modify slightly the approach in Section 2.9, where we
had
shown
temperature
that
at
equilibrium
and pressure)
(subject
AG d -- ~(i)v•
we
deal
expression equilibrium
with
(4.5.3),
charged
species;
employing
condition,
in
constant
- 0, c o r r e s p o n d i n g
the schematic chemical reaction ~(1)viAi - 0. case
to
we
In our particular
therefore
~(1)vi~i - 0 as conformity
to
with
the
adopt
the
appropriate the
earlier
discussion. As
applied
to
the
Daniell
cell
we
again
write
Zn(s)
-
Zn2+(m,) + 2e-(~) for the oxidation step on the left and Cu2+(mr) + 2e-(r) ~ Cu(s) for the reduction step on the right. then
to
be
These are
combined into the net reaction schematized by Eq.
4 J4
4. THERMODYNAMIC PROPERTIESOF ELECTROLYTES
(4.6.1), that
in w h i c h we have also included the c o m p e n s a t i n g
preserve
electroneutrality
in
the
two
anions
compartments"
We
write
Zn(s)
+ Cu2+(mz) + SO~(m z) + 2e-(r)
- Cu(s) + Zn 2+(m,) + SO~(m,) + 2e-(2). Note
that
we
have
constituents; the
two
drives
note
not
canceled
they are present
electrodes.
It
is
out
the
(4.6.1)
important
at different precisely
electronic
concentrations
this
difference
the cell o p e r a t i o n w h e n the open circuit
(4.6.1)
that for u n c h a r g e d
to
[ - ~.
This
that
is closed.
We next apply the c o n d i t i o n 7.(i)ui~i = 0 to Eq. species
at
leads
and
~u(s) + ~nSO4(s) + RT 2n a~(m,) + F~zn2+(m,) - F~so~(m,) + 2[e-(2)
-
~Zn(,) + ~cuso4(,) + RT ~n a~(m=)
+ F4cu2+(m r) - F4so~(m r) + 2[.-(r)] The ionic constituents at
the
same
corresponding is
true
standard
of
Zn 2+ and SO~ in the left c o m p a r t m e n t
electrostatic
potential
~(~),
terms in 4 cancel out from Eq.
Cu 2+ and
conditions
equilibrium
(4.6.2)
- 0.
of
SO~ on
the
right.
the
terms
in ~
can
constant-
(4.6.2)
whence
(4.6.2).
grouped
RT ~n Kq, as in Section 3.7.
solve
Eq.
2F~"
[[ _(2) - fe_(r)] - RT 2n Kq - RT 2n{a~2z(m= ) ,
the
The same
Furthermore, be
are
into
for an
We can then
for
(m,)} (4.6.3)
with RT 2n Kq -~ ~Zn(s) + ~CuSO4 - ~Cu(s) - ~ZnSO4 9
Here we have also
reintroduced
the e l e c t r o m o t i v e
force or emf,
-
the earlier
namely
by
[~ _(~) - ~ _(r)]IF. e
definition,
e
(4.6.4)
4 I5
GALVANIC AND ELECTROLYSIS CELLS
Note the following" circuit voltage' this case, is
the
that must be multiplied
difference
thermodynamic
function
state
for
F
in
which use
at
More precisely, ~ is directly related to the at the left and right
(ii) We have set up the circuit of Fig. 4.6.2 and
corresponding
inequalities
by
reversible electron flow from ~ to r. that K > 0 corresponds fact
of
in electrochemical potential
terminals.
The
by a charge,
to be compatible with the Gibbs free energy,
proper
constant T and P.
the
(i) The emf, K, is in a sense an ~open
that
the preceding
(iv)
The
emf
spontaneous,
Since ~i > [r it follows
to such a spontaneous discussion
transfers means that F represents transport.
assuming
transfer.
is based
the magnitude
(4.6.4)
is
on electron
of the charge
governed
spontaneous net chemical reaction abstracted
(iii)
solely
by
the
from (4.6.1);
can therefore introduce our prior definition AG d
-- ~ Z n 2 +
+
we
~Cu-
[~zn + ~cu2+] that involves solely the chemical potentials of the various species involved in the battery operation.
-
-
Thus,
AGd/2F
(4.6.5)
for the net chemical
reaction ~viA i - 0 as written;
AG d < 0, as expected. explicit reference
(v) In th~ final expressions there is no
to electron participation.
these quantities have their
effect
is
potentiometer
contrary
does
not
clearly
in to
measure
potential but differences electrodes.
the
(4.6.1) ; rather,
definition
what
is
often
differences
in
in electrochemical
for
a most undesirable
appellation.
~.
stated,
a
electrostatic
potential
(vi) The use of the term electromotive
nomenclature
of the
force
Unfortunately,
is
this
is now so firmly rooted that it is unlikely to be
displaced by a more appropriate The
It is not that
'canceled out' from Eq. subsumed
Correspondingly,
moreover,
preceding
discussion
terminology. presents
an
obviously
very
schematic representation of the actual processes that occur in the
operation
essentials
for
of a
the
Daniell
thermodynamic
cell.
Nevertheless,
analysis
Although we have based our discussion
have
been
on a specific
all
the
included. example,
4 [6
the
4. THERMODYNAMICPROPERTIESOF ELECTROLYTES
preceding
discussion
generalization,
to
which
is we
now
capable
of
immediate
devote
the
subsequent
presentation.
EXERCISES
4.6.1 Provide evidence to show that the emf for the combination Zn[M[Cu is the same as for the Zu[Cu couple; here M is any desired metal. 4.6.2 Provide a physical model which, on a microscopic basis, accounts for the fact that an emf is set up at the phase boundary between dissimilar substances, which permit electron transfer to occur.
4.7 (a)
GALVANIC CELLS : When
a
cell
GENERAL TREATMENT
is
functioning
reversibly,
work
is
being
performed on or by the system in transferring electric charge through
any
operation
cross
of
the
section cell
of
the
according
circuit.
to
the
reversible
generalized
equation Zce~vtAI - 0 is carried out only extent,
The
chemical
to an infinitesimal
so that it does not alter either the concentration
chemical
species
or
difference).
Then,
process
Section
electrons
(see
the
a
unit 2.9)
emf
(open
advancement involves
6A
the
through the external circuit,
of equivalents,
circuit in
the
transfer
of
potential chemical of
nF6A
where n is the number
determined by the nature
of the process,
and
where F, the Faraday (i.e. , the charge for Avogadro's number of electrons),
is 96,487
coulombs.
The work
done by
the
cell,
when the opposing emf is infinitesimally less that required for maintaining static conditions, 1.16,
for reversible processes,
other than mechanical
is nF~6~.
As argued in Section
at constant T and P, the work
is given by 6W" - -
6G.
In the present
case the cell reaction must occur spontaneously,
hence
for an
infinitesimal virtual advancement 6~, + nF~6~ = -
(6G/6~)T,e6~,
or
nF~ - - AGd,
(4.7.1)
GALVANIC CELLS
where
4 I7
AG d is
the
chemical
cell
This
in
is
increase
reaction
in
free
energy
~(1)veAI - 0 per
agreement
with
deducing Eq. (4.6.5).
the
accompanying
unit
special
the
of advancement.
case
considered
in
We had shown in Section 4.6 why one can
use the expression for the net chemical equilibrium in dealing with electrochemical processes. (b) The subsequent standard
states.
formulation
We shall
depends
on the choice
follow convention by adopting
hybrid system discussed in Section 3.7(c)"
the
(i) For pure solids
or liquids that participate in the electrochemical process, standard
state
subjected
to
is a
that
total
at
activity
for
such
(note
again
that
the
pressure
temperature of interest. vs(T,P,q:)a,q(T,P),
which
of
isolated one
substances
atmosphere
liquid,
is
at
the
As shown in Eq. (3.6.3b) the relative
species
in which
is q
given
by
represents
a s (T, P, qs)
either
x,
q/q* - I for pure materials); forming
the
component
c,
the
homogeneous
or gaseous phases,
mixtures
in
--
or
m
relative
activity so defined is almost invariably close to unity. For
of
the
(ii) solid,
the standard state is chosen to be
that in which each substance in the mixture is present at unit activity and subjected to one atmosphere at the temperature of interest.
of
these
species is specified by ao(T,P,qo) --7o(T,P,qj)aoq(T,P)qo.
The
summation
As
used
in
Eq.
(3.5.21)
the
activity
for j runs over all ionic species,
as well as over
any dissolved but un-ionized species, which participate electrochemical ao,
and
qj
for
quantities 7• illustrated
reaction. the
a•
in
individual
and q•
later
It is customary ions
by
to replace
Also,
the 7j,
corresponding
as discussed in Section 4.1,
sections.
in the
we
frequently
atmospheric pressure as the operating condition,
mean and as adopt
in which case
alq(T,l) m I for all species (~ m s,j), as may be ascertained by examination of Eqs. (3.4.10b), in conjunction with Eqs.
(3.4.12),
(3.7.15),
(3.5.17), and (3.5.20)
(3.7.16).
The equation for AG d consistent with the above choice Eq.
(3.7.12);
is
on introducing this relation in (4.7.1) we find
4 J8
4. THERMODYNAMIC PROPERTIESOF ELECTROLYTES
RT .---- ~ n
--
Kq
v, ~n a,(T,P,qs) + ~ vO ~n ao(T,P,qo)
nF
,
j
(4.7.2a) which under operating conditions of one atmosphere,
RT
RT
where
~n K q - -
Eq.
~ vj ~n (7jqj)
the same cell, (4.7.2a)
(4.7.2b)
to designate by ~
the standard emf of
in which all species are at unit activity;
from
it is seen that
RT ~o _ __nF ~n Kq
so that Eq.
AG ~
--,nF
(4.7.3)
(4.7.2a) becomes
- --
v, 2n a,(T,P,q,)
is known
depends
(P = i atm),
has been used.
(3.5.21)
It is conventional
which
reduces to
on
as
the
the
+ ~ vj ~n aj (T,P,qj) j
Nernst
choice
of
(1889).
concentration
(4.7.4), i.e. ~, does not.
(4.7.4)
Clearly,
units,
but
the
~o sum
One immediately sees the tremendous
utility of ,go measurements:
For any cell which can be set up
to simulate ionic,
solid state,
interest,
a
such
equation
,
liquid or gaseous reactions of
determination
directly
yields
the
corresponding equilibrium constant Kq. (c) It is helpful at this state to introduce a systematic nomenclature
and
analysis
cell
of
several
performance.
of
molality
in
unified is
Let
Pt
example: ml,
a
procedure
surrounded by hydrogen gas at pressure solution
particular
general
electrode,
HC~
a
permit
in
aqueous
of
The
that
explained an
terms
conventions
a
P, dip into
contact
with
a
similar solution at molality m 2, and saturated with respect to
GALVANICCELLS
AgC~,
4 I9
into which
is immersed a silver electrode.
such descriptive
verbiage
one
represents
such
To save on
a cell
by
Pt,
H2(P)] HC2 (m I, sat by H2)[HC2 (m2, sat by AgC2)IAgC2(s), Ag(s), where vertical bars
separate
different
portions
of the cell.
Pt is used here as an inert electrode material which does not participate in any oxidation processes in aqueous solution but which provides an interface for H +, Hz, e- interactions. We now introduce the
oxidative
process
reductive
process
electrons
are
external
Convention
on
given
circuit
to
always the
i:
For the cell as written
occurs
right.
off
at
the
the
right,
on
the
According left where
left to
and
move
they
are
and
this
the
scheme
through taken
the
up
by
species in solution, as illustrated in Fig. 4.6.1; conventional current flows in the opposite direction. The overall process is best visualized in terms of the two half reactions at the anode and cathode respectively. follows"
In the present scheme these read as
anodic ~1 H 2 ( P ) -
e- + AgC2(s)
-Ag(s)
overall process
H +
+
(ml) + e - , on the left,9
C~-(mz) , on
the
right;
cathodic
so
that
the
1
is representable as EHz(P) + AgC~(s) - A g ( s )
H+(m~) + C2-(mi), accompanied,
9
+
in accord with Convention (i), by
the electron flow through the external circuit from the Pt to the Ag electrode and by H + transfer from left to right. By Convention 2 the emf developed by the cell as written, under open circuit conditions,
~" -
~'l
-
-
~r
([l
-
is taken as (4.7.5)
~r)l F,
where 2 and r refer to the left and right electrodes cell as written under Convention potential
introduced
for the
I; [ is the electrochemical
in Section 4.6.
step reflects
the
process of splitting the cell operation into an oxidative
and
a reductive half reaction.
This
Convention 2 is consistent with our
prior discussion, as was shown for the general cell depicted by Fig. 4.6.1. A further check for self-consistency cell
for
infinity
which and
an
placed
additional on
the
electron
negative
is the following: is
brought
terminal,
is
up
A
from
at higher
42,0
4. THERMODYNAMIC PROPERTIESOF ELECTROLYTES
energy than the same cell for which the additional placed
on the positive
electron from the
terminal.
Hence,
electron
the movement
is
of
an
negative to the positive terminal lowers the
energy and thus the free energy,
of the cell.
The spontaneous
advancement of the cell reaction by dX requires the concomitant transfer left
of nFdX
(-)
to
potential
fi - r
right
under
concomitant
electrons (+)
through
past
near-open
change
a
difference
circuit
in
the
(4.5.3),
this
(aG/aX)TopdX pressure.
leads
a
proceeds
the
overall
reactions.
By
potential.
-
fashion by
advantage
a
to
-
Eq.
dG
-
temperature
-
and
as before. according
AGd/NF
first
dealing
to
with
is taken of the prior step in
is written
Convention
decrease
nF~,
of ~ and of
reaction
is
in the amount
According
at constant
that AG d - -
in an orderly Here,
There
yielding an overall change of
energy
determination
from
electrochemical
potential
corresponding
free
It now follows
the quantity ~o. which
to
in Gibbs
(d) The (4.7.4)
electrochemical
of
circuit
conditions.
in electrochemical
per transferred electron,
nF~SX
the external
3
one
as
a sum
of
associates
the
with
half each
half-reaction a standard oxidation potential. ~o, which is to be computed as a special case of (4.7.5): ~o _ ~
_ ~o,
where ~
(4.7.6)
and ~o are the standard oxidation
potentials
for the
half reactions at the left and right electrodes
for the cell as
written.
Extensive
Table
excerpted,
are available for specifying the ~o values;
that these quantities All
half
reactions
processes,
tabulations,
themselves in
the
from
may be positive
table
are
the sign of its emf value. (4.7.6)
necessitates
around,
change
is
take note
or negative. as
oxidative
is attended
thereby changing
That is, the operation required by that
one
take
standard values for the half reactions sign
written
4.7.1
so that the complete cell reaction must be obtained
by turning one of the half reactions Eq.
which
to by
the
for
~
and
~o
cited in the table;
formulation
(4.7.6).
the the One
GALVANIC CELLS
notes
42. I
that
(4.7.5)
indeterminacies
and
(4.7.6)
and
can
arise
from
the
equally well be w r i t t e n as ~0 _ ( ~ is any arbitrary
constant.
from
fact
sign
that
problems
(4.7.6)
_ cl ) _ (~o _ ci),
The first matter
in
could
where c 1
is dealt with by
C o n v e n t i o n 4: The emf is regarded as positive for the o p e r a t i n g cell
when
the
electrode
electrons
written
The second
on
tend
the
spontaneously
left
to
to
flow
that w r i t t e n
on
from
the
the
right.
to by Convention 5: The standard I electrode potential for the half reaction EH2(P-- I am .) = H + (a+
-
item is attended
I) + e- is arbitrarily It now
values
set at zero" E~
should be very
can
be
clear
constructed:
appropriate half cells
how
H+
=
0
Table
One
4.7.1
for
successively
to the half cell
in w h i c h
the ~o couples
the r e a c t i o n
2H2 (PH2 - i arm) is carried out on the e- + H + (all+ I) right; in the half cell to be tested all d i s s o l v e d species must -
- -
be
at
unit
pressure. negative
activity The
and
all
resulting
according
reacting
emf has
to whether
gases,
a sign
at
that
the electrode
atmospheric
is positive
on the left
or
is at
a lower or higher electrostatic potential than the electrode on the right; under
this emf represents the value of ~o for the half cell
study,
since
fo for
zero by convention. completed,
the
be
standards With
half
Their physical
the chemical
respective
can
cross
which
terminals.
operation
is
occurs.
are a measure
generate
has b e e n used
checks
in the use of Eqs.
interpretation
as
a
self
That
electrons.
thus ~
half
driven
and
in the extent
can give up electrons
~wins,'
reaction
which
to their
renders
its
in the sense that the opposing
by
and ~o are both of the
(4.7.5)
is that the emf arises
the two half reactions
entities
electrode more negative
oxidation
be
is
for other half cells whose ~o is
one is forced to undergo a reduction process. cell
electrode
tabulation can thus be constructed.
as a c o m p e t i t i o n b e t w e e n to w h i c h
cells
appropriate
One must be very cautious (4.7.6).
hydrogen
Once a set of such m e a s u r e m e n t s
determined.
consistent
standard
corresponding
secondary reference to
the
tendency
the
electrode
standard for
The spontaneous at
oxidation
the half
which emfs
reaction
to
422
4. THERMODYNAMIC PROPERTIES OF ELECTROLYTES
Table
4.7.1
SHORT TABLE
OF S T A N D A R D
EMF V A L U E S
B a l B a 2+
Ba-Ba
MglMg 2+
M g = Mg 2+ + 2e-
+2.363
AI[ AI3+
AI = AI3+ + 3e-
+1.662
Zn[ Zn 2+
Zn-Zn
2+ + 2e-
+0. 7628
FelFe 2+
Fe-Fe
z+ + 2e-
+0.4402
Call Cd 2+
Cd = Cd 2+ + 2r
+0.4029
pt [Ti2+,Ti 3+ Pb ]PbSO4 JSO~
2+ + 2r
(IN VOLTS)
+2.906
Ti 2+ - Ti 3+ + ePb + SO~ = PbSO 4 + 2e-
CulCuI I I -
Cu + I- - Cul + e-
Pt[HzIH +
H 2 = 2H § + 2e-
AgIAgBrJBrP t l C u +, Cu 2+ A g [AgC~ iC r Pt IHgl HgzC~2 ]C2PtllalIPt[Fe 2+, Fe 3+ AgIAg +
Cu +
=
A g B r + e-
Cu 2+ + e-
A g + C~- = AgC~
+ r
2C2- + 2Hg = Hg2C22 + 2e3I- - I~ + 2eFe 2 + -
Fe 3+ + e-
A g = Ag + + e-
PtlT2+,T23+ PtlC221C2Pt IMnZ+, MnO4Pt ISO~,
Ag + Br-=
SO~
T2 + - T~ 3+ + 2e2Or
= C~ 2 + 2e-
+0.3588 +0. 1852 0. 0000 -0. 0713 -0. 153
- 0 . 2225 - 0 . 2676 -0. 536 -0. 771 -0. 7991 -1.25 -1.3595
M n 2+ + 4H20 = MnO~ + 8H + + 5e-
-1.51
SO~ + 20H- = SO~ + HzO + 2e-
+0.93
PtJHzlOH-
H 2 + 2OH--
Pt I021OH-
4OH- = 02 + 2H20 + 4e-
Pt ]M n O 2 1 M n O ~
+ 0 . 369
2HzO + 2e-
MnO 2 +4OH- = M n O T +
2H20 +3e-
+0. 8281 -0.
401
- 0 . 588
GALVANIC CELLS
423
There
is
obviously
nothing
standard oxidation emfs.
compelling
in
the
One could equally well
use
of
deal with
tabulation in which all the half reactions are reversed.
a
These
data are compiled by coupling the appropriate half cell to the hydrogen cell operating according to the scheme ~H 2 (P~2 - I a t m ) -
H + (all+- i) + e-; all species must be present under standard
conditions. values
It
are
reversed
Table 4.7.1; the
half
in
reactions
reduction
be
clear
sign
that
the
relative
to
corresponding those
compiled
emf in
these new values are a measure of the tendency of
Correspondingly,
to
remove
electrons
one would write ~o _ ~
emfs.
formulation; the
should
Many
writers
from _ ~
the
electrode.
for the standard
prefer
this
particular
when used self-consistently one naturally obtains
same numerical
values
for ~o as by
the method
involving
standard oxidation emfs. (e) We provide a very elementary example to illustrate the preceding remarks. Pt, C ~ z ( P whose
operation,
Consider the cell I atm) IHC2 ( a • in
accord
with
i)
IAgC~(s), Ag(s),
Convention
I,
is
given
by
(25~ 2C~-(a_-
i) - C 2 2
(P-
I atm) + 2e-
~
2AgC~(s) + 2e- - 2Ag(s) + 2C~-(a_ = i)
= -1.3595 V =
+0.2225
v
=
-1.1370
V
,,
~o
2AgC~(s) - C~2(g ) + 2Ag(s)
(4.7.7)
- ~
One should carefully note how Convention 3 is applied:
~o
- ~;
However,
in
equation,
we
writing
~
the
may be read off from Table 4.7.1. lower half
reaction
as a reduction
need a sign reversal in converting ~o for an oxidative process to ~o for
a
reductive
process.
The
contributions
cancel in the algebraic addition process because is the same on both sides.
from
C2-
the activity
47-4
4. THERMODYNAMIC PROPERTIESOF ELECTROLYTES
One can now compute C22(P
-
i
arm)
+
-2(96,487)(-1.1370) reaction proceeds reader
should
statements"
AG~ for the net reaction
2Ag(s)
according
to
AG~
J/tool- 219,420 J/mol.
2AgC2(s)
=
-
2F~ ~
able
to
verify
=
Since AG~ > 0 the
spontaneously in the reverse direction.
be
-
readily
the
The
following
(i) If the half reactions had been written as C~-
- 21-C~z + e- and e- + AgC2 = Ag + C~-, the ~o values for the half reactions
and
however,
n-
the
total
~o
would
have
I in this case and A G ~ -
remained
unaltered;
109,710 J/mol.
(ii) If
the cell and cell reactions had been reversed according to the scheme Ag(s),AgC2(s)]HC2(a•
- I) lC22(P = I atm),Pt,
with half
reactions
2Ag(s) + 2 C ~ - ( a _ - I) = 2AgC~(s) + 2e-, 2e- + C~2(P --
i atm)
2C2-(a_-
-
I),
then
one would
1.1370 V and AG~ = - 2 1 9 , 4 2 0 J/mol. principle runs
that if Conventions
spontaneously
have
chloride,
but
reaction
can
with
under be
chlorine
standard
reversed
potential exceeds 1.1370 V.
+
This illustrates the general
in the direction
spontaneously
~o_
i and 2 yield a reaction which opposite
down, then one finds ~o < 0 and AG~ > 0. react
obtained
by
to that written
(iii) Silver tends to
gas
to
form
conditions
this
electrolysis
when
solid
silver
spontaneous the
applied
(iv) If the operation of the cell
is altered to read Pt,C~z(P )lHC~(a•
one obtains
a net reaction 2AgC2(s) - C22(P ) + 2Ag(s).
The Nernst equation
now reads
RT 2n [aA82 ] - --RT 2n ac~ - -1.1370 - ~-~ [a~c I 2F 2
-
-I.1370
RT - ~-~
in which the ratio
~n
a[a_~ct 1
RT 2F ~n ac~ 2 '
aAs/aAsCl differs
only slightly from unity and
acl 2 may ordinarily be replaced with Pc, 2. convince himself
that precisely
(4.7.8)
(v) The reader should
the same result,
Eq.
(4.7.7),
would be obtained if the net reaction had been written form AgC~(s) of
how
the
- 89 C~2(P ) + Ag(s).
in the
Thus,
the emf is independent
net reaction is balanced,
which is a physically
TYPESOF ELECTRODES
sensible
425
result.
On
the
other
hand,
AG~
does
depend
on n,
which again is a physically sensible result. The
reader
oxidation
-
experimental
should
reduction
carefully
study
potentials
the
are
manner
in which
handled
investigation of electrochemical
in
every
cells.
EXERCISES
4.7.1 Do the two celis Cu(s)ICu++l ICu+ICu(s) and PblCu+, Cu++ll Cu+ICu(s) correspond to the same reaction and do they have the same value ~o? 4.7.2 The emf of the cell ZnlZnC22(m) IAgC~(s)IAg, with various molalities m of zinc chloride, was found to be as follows at 25 ~ m (volts) m ~ (volts) , ;
",I
,'
:: ""', .
.
.
.
.
.
0.002941
1.1983
0.04242
1.10897
1.16502
0.09048
1.08435
0.01236
1.14951
0.2211
1.05559
0.02144
1.13101
0.4499
1.03279
,
0.007814 ,
,
,,
)etermine the standard potentlal 0f t h e Zn, Zn *T electrode. 4.7.3 Why does the electron concentration in the wire enter the Nernst equation? 4.7.4 Discuss the difference in operation and in between the two cells Pt, H2(P) IHC~(ml)IHC~(mz)IAgC2,Ag and H2(P )IHC2(m)IAgC~,Ag. Illustrate the difference in terms of Nernst equation.
4.8
not emf Pt, the
TYPES OF ELECTRODES
The following types of electrodes (a) pressure
'Gas'
Electrodes"
In
are in common use" this
scheme,
P is forced over an immersed,
and is bubbled through the solution. half reaction
=
H+
+ e-.
at
a
fixed
electrode
An example of this cell
is given by PtlH2(P atm), H+(c mol/liter), i ~H2(g )
gas
inert metal
corresponding to the
4~-~
4. THERMODYNAMIC PROPERTIESOF ELECTROLYTES
(b) Oxidation-Reductlon
Electrodes"
dips into a solution containing states.
An
example
corresponding
is
Here,
Electrode"
cell
(Q), as may
corresponding
(d)
PtlFe2+(cl),
Fe3+(c2),
This
is a specialization
an equimolar mixture of hydroquinone obtained from
contact with an inert metallic half
by
to the half reaction Fe 2+ - Fe 3+ + e-.
(b)"
and quinone
an inert metal
ions in two distinct oxidation
furnished
(c) The Ouinhydrone of case
Here,
be
quinhydrone
electrode.
represented
here
Metal-Metal
lon
(H2Q-Q) , is in
Schematically
by
to the half reaction H z Q -
(H2Q)
PtlH2Q ,
Q,
this
H+(cl),
Q + 2H + + 2e-.
Electrodes:
Here
metal
ions
in
solution are equilibrated with a metallic electrode of the same material. dipping
An into
corresponding which
react
example a
furnished
solution
to A g wlth
is
of
silver
Ag + + e-.
water
by
a
silver
nitrate:
AglAg+(cl),
Very active metals
obviously
cannot
be
electrode
such as Na
employed
in this
manne r.
(e) Amalgam equilibrated
with
Electrodes: its
ion
In this
setup
is dissolved
the metal
in a pool
to be
of mercury
into which is dipped a wire made of a noble metal.
This setup
is used for active metals which normally would react directly with water; mercury does not participate example
in the reactions.
is given by PtlHg-Na(cl) INa+(c2),
corresponding
An
to the
reaction Na(cl) - Na+(c2) + e-.
(f) Meta!-Insolub!e
Salt Electrodes"
contact with an insoluble
Here,
salt of the metal,
which
equilibrated with a solution containing the anion. is
illustrated
corresponding
by
the
half
to the reactions
cell
a metal
is in
in turn is This scheme
AglAgC~(s )ICe-(c),
Ag - Ag + + e- and Ag + + C~- --
AgC~, with a net half reaction Ag + C~- - AgC~ + e-.
(g) The Calomel Electrode" the widely used calomel
A special case of the above is
electrode,
where
a Pt wire
dips
into
427
LIQUID JUNCTION POTENTIALS
mercury in contact with a Hg2C~ 2 paste, which is in contact with a KC~ solution
saturated with HgzC~ 2.
Here the reactions
Hg -
Hg + + e - and Hg + + C~- _ EI HgzC~z occur
yielding
a net half
reaction
electrode
frequently
serves
Hg + C~- - 89 Hg2C~ 2 + e-.
as
electrode
a reference for
a
standard
calibration
This
because
use
standard
is
of
the
hydrogen
usually
quite
inconvenient.
EXERCISES
4.8.1 (a) The "dry cell" or Leclanche cell operates by oxidation of Zn(s) to Zn2+(aq), and by reduction of MnOz(s) to Mn2Oa(s) in the presence of NH4C~(aq), forming NH4OH(aq). Write out the half reactions and the complete reaction for this process. (b) Inclusive of a 50~ safety factor, what are the minimum masses of Zn and MnO 2 required to guarantee generation of a i0 ma current for I00 hours? 4.8.2 Devise a cell in which the half reactions Fe(CN) 64Fe(CN)6 a- and Mn 2+ - MnO 4- can be carried out. 4.8.3 Write down the half reactions and complete cell reactions corresponding to the following galvanic cell diagrams" (a) K(Hg) llKC~(a q) IAgC~(s)IAg (b) PtlFeC~2(aq,m2) llFeC~2(aq,m 3) IFe (c) Hg, HgO(s)INaOH(aq)IZn(OH)2(s), Zn (d) Pt,C~2(g)IKC~(aq)llBr-(a q) IBr2(~),et (e) Hg IHg2S04 (s ), Na2SO 4 (aq, m, ) I INa2S04 (aq, m r) ,Hg2SO 4 (s ) IHg. 4.8.4 Devise galvanic cells in which the following reactions can in principle be carried out" (a) (b) (c) (d) (e) (f)
H2(g) + ~~(Bgr) - H20(~) Zn(s) + (s) - Z n B r 2 ( a q) + 2Ag(s) 2Hg(~) + C~2(g) - Hg2C~2(s) Ag(s) + z 02(g ) _ AgO(s) Ag+(cz) ~ l-(c 2) - A g l ( s ) Pb + 2AgC~(s) - PbC~ 2(s) + 2Ag.
4.9 So
LIQUID JUNCTION far
we
juxtaposition anodic
have
POTENTIALS
bypassed
the
of two dissimilar
compartments
problems solutions
of the electrochemical
arising
from
in the cathodic cell.
As
the and
already
4~,~
4. THERMODYNAMIC PROPERTIESOF ELECTROLYTES
indicated
in the
discussion
of Section
4.6,
contact
between
such solutions produces a contribution to the overall cell emf which
ought
to be
taken
into
account.
Nevertheless,
it
is
generally dismissed as being small. On
a microscopic
because
two
dissimilar
equilibrium. if allowed
level,
the
liquid
solutions
junction
are
obviously
Interdiffusion of the various to proceed
indefinitely,
renders both solutions identical.
emf
this
arises not
in
ions takes place; process
ultimately
If the diffusion process can
be maintained at a sufficiently slow pace that the constitution of the solution surrounding the electrodes
is not appreciably
altered during the operation of the cell the junction potential problem may be ignored. surrounding
the
In these circumstances
electrodes
will
remain
the solutions
homogeneous;
no
appreciable concentration of foreign ions will be generated in either compartment,
and thus the chemical reactions associated
with
of the cell
the operation
are
strictly
reversible.
To
approximate this ideal condition one allows the two homogeneous electrolytes
to intermingle over a considerable
location well removed from the electrodes. zone
each
differential
infinitesimally infinitesimal out
from
layer the
advancement
without
of
distance
at a
Within the boundary
solution
neighboring
will
differ
layers,
and
only an
of the cell reaction can be carried
appreciably
violating
the
conditions
for
reversibility. Different
ions
in a given solution are characterized by
distinct diffusion coefficients that govern their net rates of diffusion
in
the
direction
opposite
to
the
concentration
gradient.
Since any electrolyte solution contains at least two
ions of opposite charge, a net charge separation will occur in a process,
whereby the faster ions move ahead of their slower
counterparts. the
faster
ions
state thus
sets
The resulting and
internal
accelerates
in, whereby both
the
electric slower
field
ones.
types of ions begin
retards A
steady to move
across the junction at comparable rates under the influence of a fairly steady electric field in the region of the junction. Suppose the
boundary region is large in extent,
so that
LIQUIDJUNCTION POTENTIALS
429
the transfer of an infinitesimal quantity of charge across the boundary layers does not appreciably alter the composition of each differential layer.
Charges are carried by different ions
in proportion to their transport numbers.
Suppose for a flow
of one Faraday in an infinite copy of the system from left to right a fraction t~ of the transferred charge is carried by the ith cation of valence z~, and a fraction t~ is carried by the ith anion of valence z ~ - - ] z ~ ] ; numbers.
Necessarily,
the t's are termed transference
Y.(j)t~ + Y.(j)t~ - i. At each location in
the bridging layer between solutions a flow of t• +
+i equivalents
of cation i occurs from right to left, and a flow o f equivalents
t~/Iz~[
of anions j takes place from left to right.
This
produces a net increase in Gibbs free energy of dG - 7. (t~/z~)d~ - 7. (t3/Iz3])d~3
i
(4.9.1)
j
for each layer in the junction region.
The overall change in
G and the concomitant emf for the entire junction solution is then -F[A~I
t~ d2n a ~ -- AG J - RT ~. ~A ZZ I
Rr 7. . 3
J'BA]z.~] t3 --
d2n a3 . (4.9.2)
One notes that in general the t's are themselves the composition or activity of the solution.
functions
of
One defines mean
tr.ansference numbers as
t-I -
~A t~ d~n a~
(4.9.3)
2n a~(B) - 2n a~(A) ' m
and similarly for t~; then
RT
A~,~ _ 7
[a~(B)]
t~
[i ~ Iz~l u
2n
laq (A)
t-~ - ~-
j z~
[a~(B) 2n
II
La~(A)
(4.9.4)
By appropriate regrouping of terms for cations and anions that belong together one obtains
(2 designates such a group)
430
4. THERMODYNAMIC PROPERTIESOF ELECTROLYTES
A~.~ _ ~
~
z;
i z_, I_
RT +-F
t~ , Izql
2n c,(A)
'
+ }
vI(B)
2n
_ j~ t] 2n ~,j+(B) . z]
"y:(A)
~j(A)
(4.9.5)
For very dilute solutions only the first term need be retained. It
is
clear
that
the
Junction
potentials
cannot
be
unambiguously determined because they involve the activities of individual
ions which cannot be measured
experimentally.
On
the other hand, if activities can be calculated successfully by the Debye-H(ickel limit
of
dilute
concentrations. species
relation solution
the
evaluated.
activities
are
In the
replaced
by
It is seen that at room temperature each ionic
contributes
[a~(B)/a~(A)]
then ~j may be
volts
of
the
order
of +
0.0592
(t•177
to ~j, and that the portions
log
arising
from
cations and anions tend to cancel.
Thus, unless ai(B)/ai(A ) is
of
is
order
I0
or
more
and
t•
of
order
unity
for
a
particular species,
the value of ~ at room temperature remains
well below 0.06 V.
Equation
be minimized
by
taking
(4.9.4) shows further that ~j can
several
precautions:
One
should
use
salts of the same valence type having a common cation or anion such
as
KC2,
KBr
or
concentration
of
electrolyte on both sides of the junction should be equal;
and
the transport numbers
Na2S04,
for the various
comparable.
In many practical
be
to
reduced
experimental
K2SO 4;
+0.003
V,
the
ionic species
cases of interest,
which
is
within
the
should be
~j can then range
of
error of many measurements.
As a practical matter,
liquid junction potential
are frequently minimized by use of salt bridges,
effects
involving
separate region connecting the two electrode compartments. solution in the salt bridge consists of high concentrations a
salt
in
mobilities.
which
the
cations
Interdiffusion
minimized by use of parchment,
and of
the
anions
have
various
collodion,
a
The of
comparable
solutions
or agar-agar gels.
is
4~ I
EMF CONCENTRATION AND ACTIVITY DEPENDENCE
EXERCISES
4.9. I For the cell with liquid junction Hg(2)IHg2SO4(s)IK2SO4(aq,m I) llK2SO4(aq,m2) IHg2SO4(s)IHg(~) show that under reversible operating conditions m2
~j
--
(3RT/2F) |
tK+ d2n (m-y+),
Jm
1
where tK+ is the transference number for the K + ion. 4.9.2 Derive an expression for the liquid junction potential of a concentration cell of the type AIA,+B,_(c, )lAv+B~-(cr)IA. 4.9.3 Determine the liquid junction emf for the cell PblH2(P - I atm) HC~(m - 0.01) IHC~(m - 0.1) IH2(P - i atm) IPt, given that t + - 5/6. 4.9.4 The emf of the cell AglAgNO3(a , - 10-3) IAgNO3(a= 10 -2)lAg is 63.1 mV at 25~ The two solutions are separated by a porous plug. Determine the average transference number of Ag + in the solution.
4.10
CONCENTRATION AND ACTIVITY DEPENDENCE OF THE EMF
The dependence of ~ on the activity of all gaseous or dissolved species
is manifested by Eq.
(4.7.2).
At 25~
for which the
standard electrode potentials are generally reported, one finds
_
~o
_
0.05915
uj ~ aj.q
log
a,us
(25 o C, E in volts), (4.10.1)
where the numerical value cited includes not only the
factor
2.303
for conversion
from natural
RT/F but also
(~n)
to common
(log) logarithms. To calculate ~ it is thus necessary to know both ~o and the various
activities
aj
and
as.
One
should
recall
that
j
enumerates the activities of all dissolved or gaseous species, whereas
s
phases.
refers The
to
components
standard
emfs
were
present dealt
as
with
pure
condensed
in Section
4.7;
activities for solutes were discussed in Sections 4.1 and 4.2, and the fugacities procedures
outlined
for gases may be computed according in
Section
3.1.
When
the
to the
Debye-H~ckel
432
4. THERMODYNAMIC PROPERTIESOF ELECTROLYTES
limiting
law may be applied
one has
an alternative
right-hand
side
the limiting
method
of Eq.
for c o m p u t i n g
(4.10.1).
At
room
in S e c t i o n
4.2,
activities
on the
temperature
(250C)
law reads
log 7• - - 0.5092 where
in the form shown
z+Iz_14~,
(4.10.2)
S - ~ ~(j)z~cj. As an i l l u s t r a t i o n
of this p r o c e d u r e
H2(P) IHC~(m)IAgC2(s)IAg(s),
for
which
consider
the
half
the cell Pt,
reactions
given by the pairs ~H 2(g) - H + + e- and e- + AgC2 - C~- + Ag, a
net
reaction
89 z(g)
+
AgC2(s)
-
Ag(s)
+
H+
+
are for C~-
Correspondingly,
RT -
(as+) (ac, -) (a~) 2n
-
a1~2
Considerable
.
(4.10.3)
simplification
is a c h i e v e d at one a t m o s p h e r e
and 300 K.
In that event a ~ c t ~ a ~
it
an
is
then
Finally,
excellent
_ ~o _ (2RT/F)
enables
of m o l a l i t y however,
a measurement in
solution
+ (2RT/F)
We (4.2.5),
next
then
using
We first
to
set
for H 2 gas
aH2 -- P H 2 -
, whence
of the mean molal activity of HC~ in the
tabulation
the ~ value
of s t a n d a r d
for the s c h e m a t i z e d
is used in reverse;
the mean activity
coefficients
be
The
determined.
the present
~n m~ - ~o _ (2RT/F)
the
in the following
cell.
i.e., from
procedure Eq.
2n (7• (m)).
extended form
emfs
for is
ions now
example.
set a• (m) - 7 • (m) m~ and rewrite
utilize
I.
(4.10.4)
the procedure
of emfs may
illustrated,
-
m and
one to calculate
Normally,
(a• (m) )2
Further,
~n(a• (m)).
One notes that a knowledge a solution
approximation
aH+ (m )ace_(m)
we write
- I.
Debye-Hfickel
(4.10.4)
as
(4.10.5) equation,
Eq.
EMF CONCENTRATION AND ACTIVITY DEPENDENCE
43
2v,v_
0. 5092z+ Iz_ 14~ log
On
V ~(m) -
-
+
Cm~.
(4.10.6)
v++v_
setting
4.2.2 ),
z+-
converting
introducing one finds
-
Iz_l - u + Eq.
(4.10.6),
v_-
i, ~ -
(4. I0.5 )
to
~
(see
common
Exercise
logarithms,
and using appropriate numerical
factors
(T = 25~
+0.11833
-i+0 . 5 0 9 2 ~ ] J
iog
_ ~o _ 0 I1833Cm~. (4.10.7)
Measurements of E are then taken for a variety of m~ values very
dilute
solutions,
yielding
a set of L values.
As
in
seen
from the expression on the right, a plot of the left-hand side, L, versus m~ should produce molalities where Eq.
a straight
(4.10.6)
line
in that range
is found to be valid.
slope one may determine the value of C appropriate
of
From the to the HC~
solution under study.
Extrapolation of the straight line back
to
as
m~-
0
yields
~o
the
intercept.
This
provides
a
convenient alternative method for determining the standard emf with respect to molality;
in the present case ~o _ 0.22234 V at
25~ Next, should
be
one returns noted,
to Eq.
without
(4.10.5), which was derived,
recourse
to
the
Debye-H(ickel
as
Law.
This relation may be rewritten as
log
- - 0.11833
With ~o known, m~ to
obtain
the
- log % .
(4. I0.8)
one now measures ~ at any desired value of corresponding
value
of
7•
Very
determinations of 7• are obtained in this manner. that the extended Debye-H~ckel very good approximation -0.I
Law,
as given
accurate
It turns out
in (4.10.6),
to the actual 7• (m) up to values
is
of m~
molal, but for greater HC~ concentrations it is necessary
to determine 7• (m) experimentally using Eq.
(4.10.8).
4:34
4. THERMODYNAMIC PROPERTIESOF ELECTROLYTES
One must recall that whereas Eq. (4.10.6) is unrestricted, Eqs.
(4.10.7)
uni-unlvalent
and
(4.10.8)
electrolyte
are at
must be suitably generalized
specialized
room
to
the
temperature
and
to be applicable
case
of
a
therefore
to other cases.
EXERCISES
4.10.1 (a) Devise a galvanic cell for which the reaction H2(P-I arm) + AgBr(s) - HBr(m) + Ag(s) may be carried out. (b) easurements show that at 298 K ~ o _ 0.07103 V and ~ - 0.27855 V for m - 0.02 molal. Determine v• and compare this with the value calculated on the basis of the Debye-H~ckel Theory. 4.10.2 In the operation of the cell Ag(s)IAgBr(x2) in molten LiBrlBr2(l atm) the emf at 500~ was found to be 0.7865 V when AgBr is the electrolyte, and to be 0.8085 V at a mole fraction x 2 - 0 . 5 9 3 7 . Determine the mean activity coefficient for AgBr. 4.10.3 At 5000C and I atmosphere the emf for the cell Ag(s)IAgC~(xl) in molten LiC~IC~2(I atm) was reported as follows: xI 1.000 0.690 0.469 0.136 ~(V) 0.9001 0.9156 0.9249 0.9629 (a) Determine the activity coefficient of AgC2 at these mole fractions. (b) Calculate the Gibbs free energy of transfer of one mole of AgC2 from its pure state to a solution at 500~ in which its mole fraction is 0.469. 4. i0.4 In the operation of the cell Pt, H2 (P-I atm) IHC~(c)IAgC~(s), Ag(s), Pt. at 300 K the following emf measurements have been reported: c (M) i0 -I 5x10 -2 10 .2 i0 -3 I0 -4 10 .5 I0 -6 ~(V) 0.3598 0.3892 0.4650 0.5791 0.6961 0.8140 0.93 (a) Write out the half reaction and net reaction. (b) Determine V• corresponding to c - 10 .2 , 5 x 10 -2 , 10 -I M; compare the values so determined with those calculated from the Debye -H(icke I Law. 4.10.5 Consider the cell schematized as Ag(s) IAg,m3(s)l NaC~(aq,ml) I Na(Hg)INaC~(aq,mz)INa3PO4(aq,m3)IAgC2(s). Taking account of nonideallty, derive an expression for the cell emf in terms of ml, mz, and m 3. What is the function of the Na3PO 4 in the operation of the cell? 4.10.6 Consider the cell schematically indicated as: H2(PI) ,Pt[C2HsOH , CH3NH3C2(cl), CH3NH2(c2) [AgC~(s)[Ag(s), where C2H5OH is the solvent for CH3NH3C~ which is in a saturated solution formed with solid CHsNH3C2. C2H5OH is also the solvent for CH3NH2, which is in equilibrium with gaseous CH3NH 2 that is
435
TYPES OF OPERATING CELLS
m a i n t a i n e d at pressure P2. At 25~ the emf of a cell, o p e r a t i n g under conditions where Pz - 0.983 arm and Pz - 4.15 x 10 .3 arm, is 0.697 V. (a) What is the emf of the cell w h e n P z - P 2 - i atm? (b) What is the overall reaction for the o p e r a t i o n of this cell? (c) Determine the e q u i l i b r i u m constant for the cell reaction. 4. i0.7 For the 'CaC22 cell' operating at 25 ~C, Ca(Hg) ICaC~2(m)IAgC2[Ag, one finds the following data" m (molal) 0.0500 0.0563 0.0690 0.1159 0.1194 0.1305 0.1538 0.2373 (V) 2. 0453 2. 0418 2. 0348 2. 0205 2. 0175 2. 0147 2.0094 1.9953 Determine ~ for the cell reaction and evaluate 7• (m) for CaC~ 2 in w a t e r w h e n m - 0.02, 0.2 M. 4.10.8 The results reported below pertain to the operation of the cell at 250C 9 PtlH2(latm) IHBr(aq,m)l AgBr (s)IAg. m (xl0 -4 molal) 1.262 1.775 4. 172 i0.994 18.50 37.18 (V) 0. 53300 0. 51618 0.47211 0.42280 0.39667 0.36172 m (molal) 0.001 0.005 0.01 0.02 0.05 (V) 0.42770 0. 34695 0. 31262 0. 27855 0. 23396 m (molal) 0. i0 0.20 0.50 0. 20043 0. 16625 0. 11880 Determine the activity coefficient for HBr when m 2 x 10 -4 , i0 -3 I0 -2 0 05 0 I0 0 50 4.10.9 For a cell in which the half reaction Fe(CN)~- Fe(CN)~- + e- and Mn 2+ + 4H20 - MnO% + 8H + + 5e- are to be c a r r i e d out, indicate the dependence of ~ on the mean activities of all species p a r t i c i p a t i n g in the cell reaction. 4.10.10 The following data are reported for o p e r a t i o n of the cell at 25~ 9 ZnlZnC22(aq,m) IAgC2(s)IAg(s)" m (molal) 2. 0941xi0 -3 7. 814xi0 -3 i. 236xi0 -2 2. 144xi0 -2 ~(V) I. 1983 I. 16502 i. 14951 i. 13101 m (molal) 4. 242xi0 -2 9. 048xi0 -2 0. 2211 0. 4499 ~(V) i. 10987 1.08435 1.05559 i. 03279 Determine 7• for ZnC~ 2 at m 10 -3 , 10 -2 , 10 -I molal. 9
4.11
P
"
9
9
P
9
9
TYPES OF OPERATING CELLS
The following
types of operating cells are in common use"
(a) Chemical provided
Cells"
in Section 4.7.
An example
of this type of cell was
We list a second example"
4~6
4. THERMODYNAMIC PROPERTIES OF ELECTROLYTES
ZnlZnC~2(m), reaction
AgC2(s)IAg(s),
represented
2C2-(2m).
By
the
by
which corresponds
Zn(s)
standard
+ 2AgC2(s)
to a net c h e m i c a l
= 2Ag(s)
methodology
+ ZnZ+(m)
described
earlier,
+ we
obtain
_ ~o
3RT _
~o
Here
.
2F
_
~o
_
__
2n
(azn++
a•
-
~o
it is a s s u m e d
_
~n
2F
that
[(41/S)mT•
the o p e r a t i o n
of one atm,
that a d e t e r m i n a t i o n
(4 " ii " I)
is c a r r i e d
so that a• - i.
of ~, c o r r e s p o n d i n g
the c o m p u t a t i o n
of 7• (m).
out c l o s e
in the p r e c e d i n g
(b) E l e c t r o d e made
up
of
to a g i v e n v a l u e of m,
The c o n t r i b u t i o n s
concentration reactive
of
gases
The
electrodes electrode
over
first
case
is
at c o n c e n t r a t i o n s
electrodes. Znx(cl)
The
Cells: that
In this case a cell is differ
materials
or
net
illustrated
in
which
by
involve
solely the
reactions
for
the
the
example of
equilibrium
cell
as
is e s t a b l i s h e d
when
For this
n-
Zn
written
Evidently,
a t = at,
in w h i c h
of
Zn, in
are:
leading for this case Kq
cell
RT ae - - - - ~n---, nF ar
amalgam.
the
left and r i g h t h a n d
- x Z n 2+(c) + 2xe- and x Z n 2+(c) + 2xe- - Znx(C r),
- a l / a r - I, and ,go = 0.
where
in
pressure
amalgams
c I and c r on the
to the c o m b i n e d r e a c t i o n Znx(ct) - Znx(Cr). case
have been
the e l e c t r o d e s .
Hg(c e) IZnS04(c)IZn,Hg(cr), mercury
of A g + and
analysis.
Concentration
two
to
Once a g a i n we see
C~- ions a r i s i n g from the s l i g h t s o l u b i l i t y of AgC~(s) neglected
a~t-)
2F
3RT ~n
a total p r e s s u r e
permits
RT
RT a~azncl RT - - 2n z _ ~ . ___ ~n aznct 2F a~c, azn 2F 2
-
2x if Zn x is the m o l e c u l a r
(4.11.2)
aggregation
of Zn in the
TYPES OF OPERATING CELLS
The
437
second
case
H2(P e)IHC~(c)IH2(Pr),
is
illustrated
by
the
Pt, for w h i c h the p r o c e s s e s
ce ii
read"
Pt,
Hz(P I) -
2H+(c) + 2e-, 2H+(c) + 2e- = H2(Pr) to y i e l d a net r e a c t i o n H2(PI) -H2(Pr).
Once again the e q u i l i b r i u m
constant
is unity,
~o_
0,
and therefore
RT P~ - ~ 2n --.
(4.11.3)
Pr As
expected,
whether then
~ >
AG d
Po. Third, simplify.
eliminate This yields
c
in
(6.1.15b) (6.1.9)
by
use
of
(6.1.13)
and
SHOCK PHENOMENA
mt -
529
[Vo/(V o - v)
Fourth,
- l]up
eliminate
- v p u / ( v o - v)
m via
(6.1.I0)
- u / ( v o - v).
and
solve
the
(6.1.16a)
resultant
for
u2 -
(P-
Po)(Vo- v).
Finally,
e-
eo -
which
(P
use
+
(6.1.16b)
(6.1.16b)
Po)(Vo-
is k n o w n
h
Po)(V
-
(P
(c)
We
perfect
gas
PV - n R T -
-
now
to o b t a i n
(6.1.17)
as H u g o n i o t ' s we m a y w r i t e
ho
(6.1.15a)
v)/2,
h e - e o + PVo,
-
in
+
equation.
If we
set h - e + Pv,
(6.1.18)
Vo)/2.
specialize
as a w o r k i n g
considerably
substance.
by
dealing
with
the
Then
(m/M)RT,
(6.1.19)
or
Pv - R T / M
(6.1.20)
and w.
e - cvT + c o n s t a n t
-
(Cv/M)T
w h e r e M is the m o l e c u l a r at c o n s t a n t Use
+ constant,
weight,
(6.1.21)
a n d Cv the m o l a r
heat
capacity
the
right
volume.
(6.1.21)
on
the
left
and
(6.1.20)
on
of
(6.1.17)" -
IR
(Cv/M) (T - To) - ~. ~ ( P + Po)[ (To/Po) -
(T/P) ].
(6.1.22)
30
6. IRREVERSIBLETHERMODYNAMICS
Note
the m a n n e r We
P/Po,
in w h i c h
rewrite
in terms
of w h i c h
Cv(T - To) - R ( n
Now collect
e has b e e n e l i m i n a t e d
the above
+ I)
terms
T(2C v + R + R/n)
by d e f i n i n g
Eq.
(T O
(6.1.22)
a shock
in favor strength
becomes (6.1.23)
T/n)/2.
-
of C v. by ~ -
in T and in T O 9
- (2~
(6.1.24)
+ R + IIR) To,
or
T
2Cv + R + fIR
To
2C v + R + R/If
(6.1.25)
For II >> R this
T/To ~
relation
reduces
(6.1.26)
[R/(2Cv + R)Ill.
The factor on the right appears for
to
it a new
symbol,
so f r e q u e n t l y
that we introduce
~, - R/(2C v + R) - R/(Cp + Cv).
We
then
obtain
T/T o -
(i + p,H)/(l
(6.1.27a)
+ ~,/H)
~,H
for II >> I.
At h i g h
T, Cv ~ 3R/2
for a m o n a t o m i c
diatomic
gas.
diatomic
gases respectively.
information
Hence,
on
the
(6.1.27b)
T/To
rise
~
n/4 Note
in
(d)
and diatomic
On
considerable
the
basis
n u m b e r of
or
and Cv ~ 5R/2
H/6
for
for a
monatomic
or
the route we took to o b t a i n
temperature
s h o c k e d and note that the a s y m p t o t i c monatomlc
gas,
when
limits
an
ideal
gas
for T/To d i f f e r
is for
gases.
of
the
above
interrelations
we
can
now
establish
using various
a
algebraic
531
SHOCK PHENOMENA
manipulations.
For instance"
(1) We can find the ratio
P/Po"
P/Po
from
(P/Po)(To/T) - 9(1 + #,/~)/(I + ~,ff)
- (n + ,.)/(z + ,.n) i/#, Thus, 6
(6.1.28a)
for n >> i.
(6.1.28b)
P/Po,
there exists a distinct upper limit on
for
monatomic
and
diatomic
gases,
for
very
of 4 and of large
shock
strengths. (li) Information on the mass flow velocity first using
e-
(6.1.21)
is obtained by
to determine
(6.1.29)
e o - (Cv/M)(T - To) ,
and then using this result in (6.1.15a), Eq.
(6.1.27),
and reintroducing H - P/Po.
eliminating T through This yields
u2 2~MC-~v]To[ (H- I)2] mm
(6.1.30)
~S'
H+~,
which
shows
that
there
exists
strength and mass flow velocity
a
connection
between
in a perfect gas.
(ill) We may eliminate To for the u n d i s t u r b e d medium Eq. (6.1.30) by recalling
shock from
(6.1.8) and noting that ~s - R/Cv(I +
~); on carrying out the indicated operation and taking square roots of the resultant we find"
u___I co
2 ~(~ + i)
(n - z)~l ~2 ~ + ~,
(6.1.31a)
(6.1.31b) 0.716 4~
monatomic
gas, H >> I
(6.1.31c)
32
5
6. IRREVERSIBLETHERMODYNAMICS
0.890 ~
diatomic
gas, H >> I.
(6.1.31d)
For 11 sufficiently large, u/c o > I; i.e. , the mass flow v e l o c i t y becomes
supersonic.
(iv)
Let us
examine
the
ratio
c/c o next.
We b e g i n
with
(6.1.13)
C m
U
(l
-
- (n
po/p)Co
t-
II+#a
[-.~j
(6.1.32).
-
~
,
(n
+oi
(6.1.28a).
.
.
Eliminate
u/c o in (6.1.32)
from
This yields
-
,, .
+ ~,,)]
(6.1.32)
II+p~
c
Co
[(t + ~,,n)l(n
- i) (i - ~,,1
where we had used
-
'
i
Co
1)(z
~,)
~(~ + 1)
+
1)(1
-
(n-
1) z] z/2
(n + # ,
)]
i12
2(II + #s)
.
-y(~
2 -
(6.1.33)
#,)z
This relation may be simplified by noting
from the d e f i n i t i o n
of ~, and V that ~, - (V - l)/(V + I) and i - Ps - 2/(V + I). Then
C/Co-
r
+ 1)/2v](n
+ ~,)
(6. I. 34a)
for H >> I
0.895 ~ ,
monatomic
0.926 ~ ,
diatomic
(6.1.34b)
gas, H >> i
(6. i. 34c)
gas, II >> I.
(6.1.34d)
A comparison of (6.1.34) with
(6.1.31)
establishes
that c > u;
the shock wave will always outrun the mass v e l o c i t y of the gas. c/c o - M, is called the MaGh number.
533
FIRST AND SECOND LAW IN LOCAL FORM
(d) We can write a shock equation of state by defining
-vo/v"
n-
P/Po
I'/. Then (6.1.28c) may be rearranged to read
(,7 - . , ) / ( I - ~,.).
(6.1.35)
Compare this to the case of the reversible, of state ~ - 7 7
adiabatic equation
and to the reduced isothermal equation of state
EXERCISES 6.1.1 Calculate the fractional rise in temperature for an ideal monatomic and dlatomic gas subject to adiabatic shock strengths H - I0, i00, i000. Compare with the fractional rise obtained under similar conditions for reversible adiabatic compressions. 6.1.2 The velocity of sound in water at 30 ~ is 1.528 m/sec. Find the compressibility K (l/p) (dp/dP) at that temperature. 6.1.3 (a) Assuming adiabatic conditions to apply, derive an appropriate equation for the sound velocity c in terms of T for a gas at relatively low pressure. (b) Taking V - 1.41, and an average molecular weight M - 28.9 g/tool, calculate the sound velocity in air at room temperature and the change in sound velocity in air with temperature at 273 K. 6.1.4 Prove the following relations involving shocked materials : m 2 - PPo ( P - Po)/(P - Po) u2 - (P - Po)(P0 - P)/PPo ~,- (vi ) / ( ~ + z).
6.2
IRREVERSIBLE
THERMODYNAMICS :
INTRODUCTORY COMMENTS - THE
FIRST AND SECOND LAWS IN LOCAL FORM (a)
In
the
phenomena
concluding
of
flow
part
of
of matter
and
examination of thermodynamics flow
necessarily
different
portions
involves of
a
our
study
energy,
we thus
deal
initiating
in its literal sense. nonequilibrium
given
system
with
states generally
the an
Any such in
which display
534
6. IRREVERSIBLETHERMODYNAMICS
different physical properties.
To deal with this situation we
subdivide the system into many subunits; volume
of
each
subunlt
tends
to
in the limit when the
zero,
every
intensive
and
extensive property will have been specified as a function of position. uniform
Each system
field 4s(r)
of
the
will
n
have
defined
thermodynamic been
everywhere
properties
replaced inside
by
an
41
of
a
instantaneous
the boundaries
of
the
scrutiny
of
total system. We
render
such
thermodynamics which makes
a
system
by establishing
two assertions:
subject
to
the
the Principle
of Local
(i) The instantaneous
State,
values
of
all thermodynamic quantities 4i at any given point satisfy the same
general
thermodynamic
principles
and
relations
as
the
corresponding quantities for a large copy of that small region at that
instant of time.
thermodynamics case.
of
This will permit
equilibrium
us to extend
configurations
to
the
the
present
(il) The local, instantaneous gradients in 41, and their
rates of change, do not enter the description of the states of each local system.
This point addresses the fact that at any
point r all relevant parameters are likely to be characterized by
different
gradient.
values
in contiguous
regions,
and hence,
by
a
Nevertheless, as long as the variation of ~i from one
region to the next is 'sufficiently small'
(what sufficiently
small means must be decided by experiment),
it may be left out
of account.
This represents
an assertion
that is verifiable
only by appeal to experiment. In general ~i will also depend on time; in such a case one must specify not only 41(r,t), but also a corresponding velocity function v(r,t) where
one
to describe a process.
wishes
to
restricted
interval
properties
of the
treat of
the
time.
subsystems
There do exist cases
evolution If
it
so
of
a
system
happens
remain unaltered,
in
a
that
the
and only
the
characteristics of the surroundings change, then the various ~i remain independent of t in the time interval under study and the system is said to have reached steady state conditions. more
precise
Section 6.4.
specification
of
this
state
is
furnished
A in
535
FIRST AND SECOND LAW IN LOCAL FORM
(b) In discussing properties is conventional
to represent
of inhomogeneous
extensive variables
systems
it
in terms of
specific q u a n t i t i e s -
that is, quantities per unit mass rather
than per unit volume.
When such quantities are multiplied by
the density and integrated over the volume obtains the total extensive variable. quantity element
per
unit
mass
whose
of the system one
Let 4(r,t)
distribution
over
represent a the
volume
dSr is governed by the density function p(r,t).
The
extensive variable for the entire system is then given by @(t) - ~v
P(r't)~(r't)d3r' (t)
where
-
-
(6.2.1)
"
V is the volume
enclosed by
the boundary.
One should
note that V in general may be a time variable quantity. To determine take
into
the rate of change of @ (d@/dt - @ )
account
that
not
only
the
integration limits change with time.
integrand but Reference
shows that the system whose initial boundary indicated by whose
the solid
boundaries
general
this
involves
center-of-mass may proceed from
the
are
curve
passes
schematized
by
a deformation
flow with velocity v.
in three
central
steps.
First,
of
the
also
to Fig.
the
6.2.1
is schematically
in time the
we must
dt
to a system
jagged system
curve; due
in
to a
The evaluation of d@/dt there
is a contribution
region V" encompassing the two overlapping
(v...t FIGURE 6.2.1 Change in volume of a barycentric flow. A" and A"" are boundaries adjacent to V" and V'".
;. system subjected to a the original and new
536
6. IRREVERSIBLE T H E R M O D Y N A M I C S
volumes,
drawn
as
a
shaded
region
in
contributes a quantity dt~v, (8~p/at)dar
Fig.
6.2.1.
to ~dt.
This
In the limit as
dt ~ 0, and when keeping only first order terms, one may ignore the difference between due to a
V"
and V.
Next, there is a contribution
V" that is newly
volume
occupied in the deformation
process.
This is composed of the e l e m e n t s -
p~(v.n)d2rdt, where
n is
Outer
element
the
unit
original boundary,
normal
to
the
surface
d2r a t
the
and v is in the direction of the velocity of
motion of the particles
as
they
cross
f r o m V" i n t o
V'.
It
is
transfer
of
A
clear
that
material
p~(v.n)d2r
represents
(more p r e c i s e l y ,
o f p~)
the
rate
across
the boundary
direction normal to the element of area. one
obtains
a
volume
element
of
d2r i n a
When multiplied by dt
containing
the
material
transferred in time dt across the boundary along the direction of flow.
The minus
sign arises because
n is the outer unit
normal, whereas ~dt represents the _increase in ~ in the system. (Thus,
when
v
is precisely
oppositely
directed
to n
then
a
positive contribution to ~ results in the amount dtp~vd2r. ) The overall contribution to ~dt due to the transfer just described isV"
dt L - p~v.nd2r, where A" is the bounding surface separating ^ from V'.
A
similar
from the volume V " two -
terms
may
- dt L .p~v.nd2r, arises ^ in the transfer. The latter
relinquished
now
dt~A(p~)v.nd2r,
contribution,
be
for
combined
which n
into a
differ
in
sign
magnitude as one passes from region V" to V "
- -
~A
(t)
(p~)v-nd2r + A -
and when Gauss'
-
-
single
integral,
as well
as
in
. It follows that
r ~V( t ) 8(p~)d3 "'at -'
(6.2.2)
theorem is applied (see Table 1.4.2, line (j))
one obtains
I
~V
{[a(p~)/at]
- v.(~pv)} d3r.
(t)
Equation
-
(6.2.3a)
transport equation.
is
-
often
(6.2.3a)
--
referred
to
as
the
Reynolds
FIRSTAND SECOND LAW IN LOCAL FORM
537
$
Note that if we write
Jv(t)(dp~/dt)dSr then Eq. (6.2.3a)
I
can be cast in the local form
d(p~)
a(p~)_ v.(p,~v)
I
dt
at
(6 2 3b)
-
" "
for any specific ~ which is an extensive quantity per unit mass of the system. extensive
It should be evident that if ~ is chosen as an
quantity per unit volume
rather
than per unit mass
then the density factor p may be dropped from Eq. Equation
(6.2.3b)
is
typlcal
of
whenever conservation laws apply. rate
8R/at;
i.e.,
of production this
term
form
is governed by two terms:
(or disappearance)
can
be
encountered
The overall rate of change
of the quantity p~ i R, i.e., dR/dr, (1) The
the
(6.2.3b).
traced
to
the
of R
locally,
occurrence
of
processes totally within the system, without referring to flows across
boundaries.
(il)
The balance
outflow to the surroundings,
between
influx
from or
as expressed in the divergence of
the flux vector _V'~, with J~R i Rv,_ which was earlier related to flows or transport across boundaries,
as specified by Stokes'
Law.
One should note that (6.2.3b) or its equivalent
d
-
/dt
( aR/at
)
-
(6.2.3c)
v.
is much more restrictive
than (6.2.3a),
balance
outflow,
between
dissipation,
influx,
not
polnt-by-polnt,
only local
for
the
basis.
and
in that one demands rate
system A
as
of
generation
a whole,
relation
of
but
this
a or
on
a
form
is
R
is
designated as an equation of continuity. In
certain
physical
situations
indestructible or uncreatable: destroyed
locally.
the
quantity
It can neither be generated nor
In such circumstances
8R/at,
the rate of
local generation or annihilation of R, must necessarily vanish. For this special case
dR/dt --
V-JR,
(6.2.3d)
53~
6. IRREVERSIBLETHERMODYNAMICS
which
implies
solely
by
outflow,
a
that net
local
change
changes in
in R
the
can be
balance
brought
between
about
influx
as expressed in divergence term - ['JR_. Eq.
and
(6.2.3d)
is a conservation equatlon.. (c) We next Second
Laws
in
turn
to
local
the
establishment
form.
This
will
of
be
the
done
First
and
under
the
important restriction that there be no motion of the center of mass of the local system" volume
deformations
v-
need be
O.
In these circumstances
considered"
dV/dt
= O,
no
thereby
greatly simplifying the analysis, while not unduly restricting its applicability.
Reference to a generalized treatment of the
problem with v ~ 01 shows that the present restriction involves the dropping of a P(dV/dt) the
First
Law,
and
of
term from the local formulation of a
tensorial
pressure-volume
term
appropriate to anisotropic media from the local formulation of the First and Second Laws.
However,
since we will continue to
confine our studies to isotropic media, and since in the steady state dV/dt vanishes, all results cited later are attainable by the
present,
more
restricted
approach.
We
divide
the
subsequent discussion into several subunits. (i) Consider a system in which n different chemical species k (k-
I, 2,...,n) are subject to r distinct chemical reactions
(~ - 1,2,...,r).
In an extension of the procedure of Section
2.9 we now represent the ~th chemical reaction by X(k)VktAk -- O, where
the Vke are
the
appropriate
stoichiometry
coefficients
matched to the various chemical species A k in reaction ~. quantities may have either sign, Then,
if AI represents
designate dAi/dt. or
the
each
of
as discussed advancement
advancement
of
this
of
in S e c t i o n
2.9.
reaction
~ we
reaction
by
~i -
The product PkVki~i then represents the mass production
depletion
chemical
rate
a unit
These
rate
per
reaction.
species
may be
unit
volume
Furthermore, subject
to
of
we
species
allow
any
for
k
in
the
conservative
the
fact
~th that
external
IS. R. de Groot and P. Mazur, Nonequilibrium Thermodynamics (North-Holland, Amsterdam, 1962).
FIRSTAND SECOND LAW IN LOCAL FORM
force per
unit
S3 9
mass fk --- _V~k, where ~k is an appropriate
time-independent potential per unit mass. that while v -
0, individual particle
It should be noted
flows do not vanish;
in
fact, we write the mass flux vector for species k as Jk m PkVk, where Pk is the density, unit mass,
of the kth species.
ECk)PkV_k/P -- I - (it)
Note that in the present case
O.
We now t u r n
of mass.
and v k the average drift velocity per
to an analysis
of
the
law of conservation
The time rate of change of mass for a given species
within a fixed volume is equal to the net rate of influx across the bounding surfaces plus the net rate of generation of k in chemical reactions.
Thus,
r
(dPk/dt)d3r ---
Pk[k "nd2r +
X ~--I
(6.2.4)
PkVkeWtd3r,
where the minus sign occurs because n is the unit normal vector directed toward the outside. the
last
negative;
term
in
(6.2.4)
Observe that for some species k
is positive
for
others
it
is
this balances out in such a manner that there is no
net formation or disappearance that occur locally. 1.4.2),
and
Eq.
of total mass
in the reactions
On introducing Gauss' Law (line (j), Table
(6.2.4) reduces to
r
dPk/dt
1-
V.J k +
(k-
..., n).
(6.2.5)
expressions for energy
balance.
~ PkVk,~,,
i, 2,
s
(ill) We
next
construct
Since by assumption v of
the
total
center
of mass
potential
energy
0, the kinetic energy term for motion vanishes. density
The
rate
of change
p~ m Z(k)Pk~,
so
long
of
the
as
one
considers only time-independent potentials ~k, may be determined from
(6.2.5)
by
multiplication
subsequently summing over k"
of
both
sides
with
~k
and
S40
6. IRREVERSIBLETHERMODYNAMICS
n
--z-(
dp~ dt
+ k-I
r I
+
x k-I
n X Pk~"k,', - -
(n V.
I ~_Jk
i-i k-i
Here
we
noted
n
-
have
written
V.(~Jk)
(6.2.6)
I Jk'fk k-I
k-i
-- ~ V . J k
+ Jk'V~
the fact that Z(k)Pk~Vkl--0 because
and
we
have
the total potential
energy of the system is conserved in every chemical reaction. In the preceding discussion and in what
follows below we
have introduced to the bar symbol to emphasize that we refer to a specific mass
(i.e.
per unit mass)
flux vector;
quantity
although ~ J k
is dimensionally
quantity.
Note
that Jk is a
has a strange appearance
correct"
Jk-
PkVk, whence
this
~Jk
-
#k~/k iS the rate of transport of potential energy density. (d)
As
a
Thermodynamics
further which
step
we
requires
introduce that
local system be strictly conserved.
the
the
total
First
Law
energy
of
of the
This means that any change
of total energy U can occur solely through influx or outflow of energy across boundaries.
This flux will be characterized by
the flux vector Ju, which corresponds to the energy density pu; m
Ju
-
The
puv.
total
energy
balance
equation
thus
reads
..Iv{(dpu)/dt}d3r - - JAJu-{~dZr; with the aid of Gauss' Theorem we then obtain
the
strictly
local
equation
for
conservation
of
total energy density:
(6.2.7)
d(p~)/dt - - V.J u. (iv) specific
We
now
introduce
energy u and the
relation u -
the
distinction
internal
specific
between energy
total
e by
the
e + @; if the center of mass of the system were in
motion then an additional kinetic energy term would have to be ~ .
added.
The
readily
grasped by an example.
a
a m
distinction between u and e may perhaps
gravitational
potential"
Consider Changes
in
be most
a system placed
in
its energy are then
541
FIRST AND SECOND LAW IN LOCAL FORM
specified by d(Mgz)
- gzdM + Mgdz.
The quantity on the left
refers to the overall change of energy du. the
right
corresponds
transported location
z;
to
a
from
infinity
the
internal,
case
de.
The
displacement
of
the
to the
thermodynamic
second
system
coordinates
leading to a change term,
entire
The first term on additional
and accreted
system have now been altered, energy,
where
Mgdz,
system
mass
at the of
the
the
in internal
corresponds
in
is
to
a
gravitational
potential #s; thus the potential energy of the entire system is uniformly
altered,
but
the
system remain unchanged. by the quantity d~s. + Mgdz corresponds
thermodynamic
coordinates
of
the
This latter alteration is symbolized
In thls elementary example d(Mgz) - gzdM
to d(pu) - d(pe) + d(p~s).
(v) The First Law of Thermodynamics
is frequently written
out in terms of the quantity pe rather than pu, and this is the path we shall follow here.
We specify the total energy flux as
n
(6.2.8) k-I
The reason for the JQ nomenclature
is that we have consistently
regarded the net energy flux density V-J u as arising from the performance
of work,
and heat flow. the
term
V-~Ck)~Jk;
identified
as
corresponding Let
us
the effects of potential
The first a
the net
two contributions
remaining heat
energy
transfer
energy changes, are contained
flux
_ V.JQ,
must
thus
involving
in be the
flux vector JQ. subtract
(6.2.6)
from
(6.2.7);
this
yields
an
expression for the rate of change of internal energy density" n
d(p~) - _ dt
V-JQ + -
~ Jk-fk. k=l
Equation (6.2.9) represents
(6 2 9) " " the local formulation of the First
Law of Thermodynamics when there is no motion of the center of mass.
Note again that Eq. (6.2.7) and (6.2.9) are not averaged
542,
6. IRREVERSIBLE T H E R M O D Y N A M I C S
over a finite volume but must be
obeyed
locally.
Also,
Eq.
(6.2.9) does not satisfy the conservation law except when fk m 0 for all k. energy
This situation arises because e is not the total
density
unless
the
system
is
free
from
all
external
forces. (e) The
Second
Law
is handled
by
recourse
equation (1.18.34) in the form (for d V - 0 ) Set dS - d(sV) - Vd(p~),
~k
~kMk,
-
nk
-
n~/Mk
-
dE - Vd(p~),
TdS-dE
to
the
Gibbs
+ ~(k)~kdnk.
and write (6.2.10)
pkVlMk
Then
T d (p~) d (p~) dt + ~ ~k dt k
Finally,
introduce
dPk dt
"
(6.2.5)
(6.2.11)
and
(6.2.9)
into
(6.2.11);
this
yields
n
-
where A e - -
+ z k
r
+ x k-i
+ z ~=i
~(k)PkVki~k is called the chemical affinity.
that 3 k and ~e refer to specific quantities.
However,
Note
the above
quantities occur exclusively in combinations such as 3.fk, ~kJk, and ~tNe; this permits the following alternative interpretation" 3 k is the flux in moles time,
~k is the
of k past unit cross
usual partial molal
Gibbs
section
in unit
free energy,
fk =
- - V ~ is the negative of the potential energy gradient per mole, Vke~ ~ is the rate of molar concentration change of species k in reaction ~, and A t the corresponding affinity. will be used interchangeably. We now rewrite
(6.2.12)
as
These quantities
543
FIRSTAND SECOND L~W IN LOCAL FORM
n d(pg)_dt
) j ~kJk /T
V-[(JQ-
n - (I/T 2) JQ.VT + (I/T 2)
~. ~kJk .VT k-I
k-I n
-
(I/T)
r
~. JTk.(~T~k - fk) + ( l / T ) k-i
~. ~,A,. ~-i
(6.2.13)
This relation can be split into two types of contributions: first
term
in
(6.2.13)
T-I(_JQ - ~.(k)~kJk). clearly
makes
involves
the
divergence
In the context of Eq.
sense
to define
of
(6.2.13)
an entropy
The
the
flux
it therefore
flux vector
by
the
following relation:
n
Js " (I/T){Jo -
The
remaining
~- ~kJk} 9 k-I
terms
(6.2.14)
on the right
of
(6.2.13)
must
represent
source terms if Eq. (6.2.13) is to be interpreted as an entropy balance equation -
V.J s we
generation
d(p~)/dt--
can
express
0
V.J s + 0. as
the
Having thus identified
rate
of
n
- - (l/T) Js'_VT - (l/T)
recognizing
that
molar
ge.neralized
the
r
_Vk~k -- _fk -- V(~k + ~k) -- V~k,
specific
potential
chemical
great fundamental Note
~
chemical
can be
potential
interest,
that we have
~'k"
potential
combined Equation
succeeded
in setting
into
the Second Law,
- - V-J s + 0,
which should be contrasted with (6.2.7).
the
a specific
(6.2.15) up
thus
P-k and
as will be demonstrated
equation for entropy density, [d(ps)/dt]
density
~. Jk'_V~k + (l/T) ~. wtA, _> 0, k-i ~=i (6.2.15)
in which we have written external
entropy
locally as follows"
is
of
later.
a continuity
in local form, (6.2.16)
We have also achieved
S44
6. IRREVERSIBLETHERMODYNAMICS
an important
separation.
The
term-
V-J s specifies
the net
transfer of entropy density across the boundaries of the local system,
whereas
generation
due
8 to
refers
to
the
(irreversible)
rate
of
processes
within the local volume element.
entropy
density
occurring
totally
In subsequent
sections
this
latter quantity will play a cardinal role. (f) A reformulation eliminating JQ between
of (6.2.15) may be achieved by first
(6.2.8) and (6.2.14);
one obtains
n
Ju -
-
(6.2.17)
I rk_J -
k-1
In the case of a single species
(k-
considered
transported
as the total
energy
Js/J1
species i, UI, likewise,
unit mass of species I, S I. U I-* - T S ~
TS - Pl.
Ju/J1
may be
per unit mass
of
is the total entropy carried per Thus Eq.
- [i, or to its equivalent,
analog of H -
I) the ratio
(6.2.17)
-E *l -
Now substitute
TS~-
(6.2.17)
specializes
to
~i , which is an into (6.2.15);
then a slight rearrangement yields n
- - (I/T 2) Ju'VT + +
r ~ (I/T)~,A, ~-I
-Ju'V(I/T)
-
Z
n
Z
(rk/T2)Jk'VT -- (I/T)
k-I
Jk'V[k
k-i
n r 7. Jk'V(rk/T) + ~ (I/T)~,A, _> 0. k-i ~-i
The form of (6.2.15)
and (6.2.18)
(6.2.18)
is highly significant.
In each case the rate of local entropy density generation, to
irreversible
processes
occurring
totally
within
a
due
local
volume element, may be written as a sum of terms of the general form 8 - E(j)Jj-X_~ >_ O, wherein the Jj represent either general fluxes or reaction velocities, forces.
and the X_~ represent generalized
As already explained in Section 2.2, this nomenclature
arises because 8 - 0 can only occur when equilibrium prevails,
LINEAR
PHENOMENOLOGICALEQUATIONS
545
m
at which
point both X j and Jj go to zero
sense Jj is a response
to the imposition
external
Of
force
development forces
and
-VT),
Such
thermodynamics pairwise
pairs
said
are
(wt, Ae/T);
(Jk/T, ~r~k/T), and (wl,
that no unique of a
on the system of an
importance
that occur
to
In this
to
our
future
are the particular
in the expression constitute
in Eq.
A,/T).
(6.2.18)they
(J,/T,
are
It is therefore
set of such pairs may be set up;
8 -
conjugate
In Eq. (6.2.15) these pairs are respectively
(Jk/T,-~k),
-VT-I),
great
of irreversible fluxes
~.(j)Jj-X_j. variables.
X_j.
for all J.
(Ju,
obvious
the selection
set as a starting point for further development
is then
simply a matter of convenience. Since
a
corresponding
flux
may
be
considered
to
be
~driven'
by
a
force, no flux can occur without a force field,
in which case all irreversible phenomena cease; 8 now vanishes, and Eq.
(6.2.16) becomes a conservation condition for entropy.
EXERCISES
6.2.1 Derive the equation of continuity for a system of constant mass in the form dp/dt + V . p v - O. 6.2.2 Explain why for reactions occurring totally within a system ~ does not contain terms in reaction velocities or affinities [see Eq. (6.2.9)], whereas ~ does: see Eq. (6.2.13). Hint: Consider the possible sources for reaction energies, and how such reaction energies would be dissipated. 6.2.3 Derive the equation r dpNk/dt - - l'_Jk + Z PkUk~k k-1
and explain its relation to the equation of continuity. 6.2.4 In Eqs. (6.2.8) and (6.2.9) JQ was identified as a heat flux vector, yet this quantity corresponds to e, the internal energy density. Consult Sections 1.8 and 1.16 and explain again why this particular designation is appropriate.
6.3 THE LINEAR PHENOMENOLOGICAL
EQUATIONS,
AND THE ONSAGER
RECIPROCITY CONDITIONS (a) We had earlier derived an equation for the local rate of entropy density production when no volume changes occur:
546
6. IRREVERSIBLETHERMODYNAMICS
- (Sps"/ST) - -
T-IJs.VT - T -I
n
r
~ Jk.V[k +
~ ~,(A,/T) _> O.
k-I In circumstances
where
no
2-1
chemical
(6.3.1)
reactions
take
where no particle fluxes occur 8 - - T-IJs.VT _> 0. - 0 only if equilibrium prevails, attain a value
of zero.
place
and
One can have
in which case Js and VT both
In the absence
of any particle
flux
the quantity T-IJs represents the heat flux JQ/T 2, as is evident from
(6.2.14).
JQ.V(I/T).
Equation
According
to
(6.3.1) our
'driven' by a gradient in I/T. problem one postulates the
linear
now
reads
standard
interpretation
JQ
is
In the simplest approach to the
that JQ is linear
relationship
8 - - T-2JQ-VT -
must
be
in V(1/T) ; moreover,
homogeneous,
so
that
no
additive constants prevent JQ from vanishing simultaneously with V(1/T).
The postulated relation
JQ- I..V(1/T) should
(6.3.2a)
hold
under
equilibrium.
Here
temperature quantity, Equation
and
conditions L-
L(T,p)
density;
one
not is
a
too
far
scalar
cannot
removed
function
introduce
a
have
of
the
tensorial
as this would generate a set of preferred directions. (6.3.2a) may be rewritten as
JQ - - (L/T 2)VT - - ~VT,
which
from
represents thus
correctness
Fourier's
recovered of
the
(6.3.2b)
Law of Heat
a well-known procedural
law,
methods
Conduction which
(1818).
attests
adopted
here.
to
We the The
quantity ~ is known as the thermal conductivity of the medium. The same argument may now be repeated
for the case where
again no reactions occur, the temperature is held constant, but now a particle flux of one type is permitted. reduces
=-
Equation (6.3.1)
to
_> o .
(6.3.3)
LINEAR PHENOMENOLOGICAL EQUATIONS
54"/
We now revert to the use of molar quantities
for which Ji.V~i -
(ml/V)v.V(Gi/m i) - (nl/V)v.V(Gi/n i) -Ji.V~i.
We shall omit the
tilde for ease of notation. V~i
is
a
driving
conjugate
molar
is invoked,
force
The form of (6.3.3) to
which
flux for species
T-iJi
i.
is
Again,
suggests
the
responding
a linear
relation
of the form
Ji - L" (T,p)V~i , which
that
connects
(6.3.4a)
the
force
and flux.
The
been absorbed in the definition of L'.
extra
factor
Equation
the form of Fickes Law (1856) for diffusion,
T -I has
(6.3.4a)
is in
usually w r i t t e n in
the form
J - - D Vc,
(6.3.4b)
where D is the diffusion of particles. for
in the
particle
The
absence
flows
(RT/c)Vc,
Eqs.
(6.3.4a) ~ -
Eq.
~
+
are
or when RT
~n
equivalent;
only u n c h a r g e d
c.
Thus,
V~
potential
and Je is the charge
- V(~/e)
and ~ the prevailing
back
from
molar
6.3.2.
concentration
are charged,
-
then one
in the form Je = L"(T,p)V(~/e),
charge,
Now write V(~/e)
Exercise
field, -
if the particles
(6.3.4a)
is the electronic
shift
(6.3.4b)
so that D - - (L'RT/c).
may recast
- eJ.
~
and c, the c o n c e n t r a t i o n
and
of electric
occur,
On the other hand,
-e
coefficient
flux;
Je-
- V~, where ~ is the chemical
electrostatic
to atomic
Suppose
where
potential;
quantities
further
that
the
in the system remains uniform.
is
such a
considered charge
in
carrier
In that event one
finds
_fl'e -
where
L"(T,p)(-
E
V~)
-
L"(T,p)E
is the electrostatic
formulation conductivity.
of
Ohm' s
Law
-
aE,
field. (1826) ;
(6.3.4c) Equation a
is
(6.3.4c) the
is one
electrical
~48
6. IRREVERSIBLETHERMODYNAMICS
(b) These examples concept
of
a
set
suffice to illustrate
of processes
for
which
the more general
the
rate
of
local
entropy density production has the form 8 - ~(J)JJ'X_0, where the Jj are all forces.
the relevant
Pairs
fluxes
of variables
and the Xj,
the corresponding
Jj, X_j, satisfying
this particular
form for 8 are said to be conjugate.
For every such pair one
postulates
of
a
direct
proportionality
the
form
J•
-
LIjX_0
between the various conjugate Ji, Xj pairs.
The validity of the
llnearlty
a
principle
experimental
data
thermodynamics. microscopic
ultimately
and
rests
in no way
However,
on
invokes
comparison
with
a new principle
of
in lowest order of approximation,
a
theory of heat and of mass flow does lead precisely
to such linear relationships. When more than one force at a time acts on a local system, a corresponding number of flows must occur simultaneously. this event
one enlarges
down simultaneous Jl-
LIIXI
JnThese
equations
LIzX2
+
2x2
relations
equations, -
+
on the original
+
"'"
+
+
...
+
postulate
In
by writing
of the form
Lln_Xn
(6.3.5)
are known
as phenomenological
or macroscopic
in which the various Jj, Xj satisfy the relationship
E(j)Jj-X_0 for
phenomenological
i 0;
I) then ~A > O, so
If two processes
thus,
for
occur
example,
it
is
possible to have ~IAI < 0 if ~2A2 > I~IAII. (b) Consider If
the
third
elementary
two reactions
process
reactions
A is
=
C
the
of the type A = B and B = C.
is
not
same
as
feasible the
the
number
linearly
reaction equations;
uncoupled.
If A = C is a feasible reaction the three processes
coupled;
generally,
coupling
occurs
are
of
of
independent
are
the reactions
number
whenever
said to be
there
is a
redundancy in the number of reaction steps. For situations not far removed from equilibrium (what this implies usual
will
linear
be
fully
relations
present context
5R. Haase, (Addison Wesley,
documented between
later), fluxes
one postulates
and
forces.
In
the the
(A, should not be confused with A)
Thermodynamics Reading, Mass.,
of Irreversible 1968).
Processes
580
6. IRREVERSIBLETHERMODYNAMICS
R ~r == X a r , A ,
(r
-
(6.11.1)
I, 2, . . . , R ) .
s-I
Coupled
equations
coefficients:
are c h a r a c t e r i z e d
a=, ~ 0 for r ~ s.
by nonvanlshing
The d i s s i p a t i o n
cross
function
is
given by
R
R
(6.11.2)
~r--~ s--~ ar'ArA" >- 0.
(c)
It
reactions
is
instructive
to
specialize
to
the
case
of
two
(R - 2):
~I = a11A1 + a12A2 a21
-
a12
(6.11.3)
(~2- a21A1 + a22A2. Then
(6.11.4)
-- aliA21 + 2aI2AIA 2 + a22A ~ >_ 0,
which
requires
Where
there
a11 >_ 0,
and a 1 1 a 1 2 -
is no coupling,
a22 >_ 0 (see
Section
2.2).
a12 - a21 - 0; in that event,
~IAI -
a11A12 >_ 0 and ~2A2 - a22A 2 >_ 0. We n e x t
inquire
approximation.
For
characterized general
~
-
eliminate
as to the range
by
n
this
purpose
I
deformation
+
~o(xl, .... ,xn+l) and
xn+ I
of v a l i d i t y
between
the
note
A
two
that
-
But
well,
the
zero
measure
of
conditions
the
deviation
deviation
at w h i c h
of
of A from the
the x i a s s u m e
x~. It is t h e r e f o r e
reasonable
in A w h i l e
all x i - x~;
lowest
setting
order,
one o b t a i n s
a
linear
system
xl,
is
then
in
Ao(xl,...,xn+l) ; one
functions
a n d A - A(xl,...,xn+l).
that
if
coordinates
~(xl,...,Xn,A) so
of the
system
to
obtain
may ~
-
as A ~ 0, ~ ~ 0 as may
from
be
the
taken
to e x p a n d ~ as a T a y l o r ' s only
a
equilibrium
their e q u i l i b r i u m v a l u e s
on r e t a i n i n g
as
the
xI -
series term
of
CHEMICAL PROCESSES
-
S8 I
(a~/aA)~r~o
On writing ~ -
a
I
A
~
+
(i-
...
1,2,...,
n).
(6.11.5a)
aA, one finds that
(ao~/aA)=i.o i
identifies
(6. ll.5b)
the coefficient
a.
To check on the adequacy of the linear approximation we now introduce
~
==
~
the law of mass action in the form
C i
- -
corresponding
C,j~',i ,
SO"
(6. l l . 6 a )
to the schematic
reaction
where, as usual, the v's are stolchlometry coefficients and the A's are reacting species; for
the
forward
(6.11.6b).
=
=
reverse
Now rewrite Eq.
process
(6.11.6a)
as
written
in
Eq.
as
- k~c,',),
u~(1
in which ~ k
and
K and m" are reaction rate constants
(6.11.6c)
is the rate of the forward reaction,
m~c~
i, and
J L
~'/~.
Referring back to Section 2.14 one notes that the affinity may be reformulated
A
-
-
Z
v lpl
"
as
RT ~n K -
RT ~
ce
,
(6.11.7)
!
where K is the equilibrium constant appropriate to the reaction (6.11.6b)
when
~ is referred to the standard chemical poten-
5 8'2
6. IRREVERSIBLETHERNODYNANICS
It now follows that Ke -A/R7 -
tlal.
is introduced ~f(l
-
in (6.11.6c)
c e ; w h e n this e x p r e s s i o n
one flnds
kKe--AIRT).
- -
Now at equilibrium, that k K -
(6.11.S)
~ - A - O; according to (6.11.8)
i, so that one obtains
the final
this means
expression
in the
form
~f(1
~0 -
-- e --A/RT),
which exhibits
(6.11.9)
an exponential
It is now clear
of w on A.
that the p o s t u l a t e d
linear
dependence
in
(6.11.5) obtains only if IA/RTI