Relations between heat capacities explained

In thermodynamics, the heat capacity at constant volume,

CV

, and the heat capacity at constant pressure,

CP

, are extensive properties that have the magnitude of energy divided by temperature.

Relations

The laws of thermodynamics imply the following relations between these two heat capacities (Gaskell 2003:23):

CP-CV=VT

\alpha2
\betaT

CP=
CV
\betaT
\betaS

Here

\alpha

is the thermal expansion coefficient:
\alpha=1\left(
V
\partialV
\partialT

\right)P

\betaT

is the isothermal compressibility (the inverse of the bulk modulus):

\betaT=-

1\left(
V
\partialV
\partialP

\right)T

and

\betaS

is the isentropic compressibility:

\betaS=-

1\left(
V
\partialV
\partialP

\right)S

A corresponding expression for the difference in specific heat capacities (intensive properties) at constant volume and constant pressure is:

cp-cv=

T\alpha2
\rho\betaT

where ρ is the density of the substance under the applicable conditions.

The corresponding expression for the ratio of specific heat capacities remains the same since the thermodynamic system size-dependent quantities, whether on a per mass or per mole basis, cancel out in the ratio because specific heat capacities are intensive properties. Thus:

cp=
cv
\betaT
\betaS

The difference relation allows one to obtain the heat capacity for solids at constant volume which is not readily measured in terms of quantities that are more easily measured. The ratio relation allows one to express the isentropic compressibility in terms of the heat capacity ratio.

Derivation

If an infinitesimally small amount of heat

\deltaQ

is supplied to a system in a reversible way then, according to the second law of thermodynamics, the entropy change of the system is given by:

dS=

\deltaQ
T

Since

\deltaQ=CdT

where C is the heat capacity, it follows that:

TdS=CdT

The heat capacity depends on how the external variables of the system are changed when the heat is supplied. If the only external variable of the system is the volume, then we can write:

dS=\left(

\partialS
\partialT

\right)VdT+\left(

\partialS
\partialV

\right)TdV

From this follows:

CV=T\left(

\partialS
\partialT

\right)V

Expressing dS in terms of dT and dP similarly as above leads to the expression:

CP=T\left(

\partialS
\partialT

\right)P

One can find the above expression for

CP-CV

by expressing dV in terms of dP and dT in the above expression for dS.

dV=\left(

\partialV
\partialT

\right)PdT+\left(

\partialV
\partialP

\right)TdP

results in

dS=\left[\left(

\partialS
\partialT

\right)V+\left(

\partialS
\partialV

\right)T\left(

\partialV
\partialT

\right)P\right]dT+\left(

\partialS
\partialV

\right)T\left(

\partialV
\partialP

\right)TdP

and it follows:

\left(\partialS
\partialT

\right)P=\left(

\partialS
\partialT

\right)V+\left(

\partialS
\partialV

\right)T\left(

\partialV
\partialT

\right)P

Therefore,

CP-CV=T\left(

\partialS
\partialV

\right)T\left(

\partialV
\partialT

\right)P=VT\alpha\left(

\partialS
\partialV

\right)T

The partial derivative

\left(\partialS
\partialV

\right)T

can be rewritten in terms of variables that do not involve the entropy using a suitable Maxwell relation. These relations follow from the fundamental thermodynamic relation:

dE=TdS-PdV

It follows from this that the differential of the Helmholtz free energy

F=E-TS

is:

dF=-SdT-PdV

This means that

-S=\left(

\partialF
\partialT

\right)V

and

-P=\left(

\partialF
\partialV

\right)T

The symmetry of second derivatives of F with respect to T and V then implies

\left(\partialS
\partialV

\right)T=\left(

\partialP
\partialT

\right)V

allowing one to write:

CP-CV=VT\alpha\left(

\partialP
\partialT

\right)V

The r.h.s. contains a derivative at constant volume, which can be difficult to measure. It can be rewritten as follows. In general,

dV=\left(

\partialV
\partialP

\right)TdP+\left(

\partialV
\partialT

\right)PdT

Since the partial derivative

\left(\partialP
\partialT

\right)V

is just the ratio of dP and dT for dV = 0, one can obtain this by putting dV = 0 in the above equation and solving for this ratio:
\left(\partialP
\partialT

\right)V=-

\left(\partialV\right)P
\partialT
=
\left(\partialV\right)T
\partialP
\alpha
\betaT

which yields the expression:

CP-CV=VT

\alpha2
\betaT

The expression for the ratio of the heat capacities can be obtained as follows:

CP
CV

=

\left(\partialS\right)P
\partialT
\left(\partialS\right)V
\partialT

The partial derivative in the numerator can be expressed as a ratio of partial derivatives of the pressure w.r.t. temperature and entropy. If in the relation

dP=\left(

\partialP
\partialS

\right)TdS+\left(

\partialP
\partialT

\right)SdT

we put

dP=0

and solve for the ratio
dS
dT
we obtain
\left(\partialS
\partialT

\right)P

. Doing so gives:
\left(\partialS
\partialT

\right)P=-

\left(\partialP\right)S
\partialT
\left(\partialP\right)T
\partialS

One can similarly rewrite the partial derivative

\left(\partialS
\partialT

\right)V

by expressing dV in terms of dS and dT, putting dV equal to zero and solving for the ratio
dS
dT
. When one substitutes that expression in the heat capacity ratio expressed as the ratio of the partial derivatives of the entropy above, it follows:
CP=
CV
\left(\partialP\right)S
\partialT
\left(\partialP\right)T
\partialS
\left(\partialV\right)T
\partialS
\left(\partialV\right)S
\partialT

Taking together the two derivatives at constant S:

\left(\partialP\right)S
\partialT
\left(\partialV\right)S
\partialT

=\left(

\partialP
\partialT

\right)S\left(

\partialT
\partialV

\right)S=\left(

\partialP
\partialV

\right)S

Taking together the two derivatives at constant T:

\left(\partialV\right)T
\partialS
=\left(
\left(\partialP\right)T
\partialS
\partialV
\partialS

\right)T\left(

\partialS
\partialP

\right)T=\left(

\partialV
\partialP

\right)T

From this one can write:

CP=\left(
CV
\partialP
\partialV

\right)S\left(

\partialV
\partialP

\right)T=

\betaT
\betaS

Ideal gas

This is a derivation to obtain an expression for

CP-CV

for an ideal gas.

An ideal gas has the equation of state:

PV=nRT

where

P = pressure

V = volume

n = number of moles

R = universal gas constant

T = temperature

The ideal gas equation of state can be arranged to give:

V=nRT/P

or

nR=PV/T

The following partial derivatives are obtained from the above equation of state:

\left(\partialV
\partialT

\right)P =

nR
P

 =\left(

VP\right)\left(
T
1
P

\right)=

V
T
\left(\partialV
\partialP

\right)T =-

nRT
P2

 =-

PV
P2

 =-

V
P

The following simple expressions are obtained for thermal expansion coefficient

\alpha

:
\alpha=1\left(
V
\partialV
\partialT

\right)P =

1\left(
V
V
T

\right)

\alpha=1/T

and for isothermal compressibility

\betaT

:

\betaT=-

1\left(
V
\partialV
\partialP

\right)T =-

1
V

\left(-

V
P

\right)

\betaT=1/P

One can now calculate

CP-CV

for ideal gases from the previously obtained general formula:

CP-CV=VT

\alpha2
\betaT

 =VT

(1/T)2
1/P

=

VP
T

Substituting from the ideal gas equation gives finally:

CP-CV=nR

where n = number of moles of gas in the thermodynamic system under consideration and R = universal gas constant. On a per mole basis, the expression for difference in molar heat capacities becomes simply R for ideal gases as follows:

CP,m-CV,m=

CP-CV
n

=

nR
n

=R

This result would be consistent if the specific difference were derived directly from the general expression for

cp-cv

.

See also

References

This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Relations between heat capacities".

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