160 4 The Thermodynamics of Real SystemsEquation (4.2-10) is one of a class of equations calledMaxwell relations. A common
use of these relations is to replace a partial derivative that is hard to measure with
one that can more easily be measured. For example, it would be difficult to measure
(∂P/∂S)V,n, but much easier to measure (∂T /∂V)S,n.The Maxwell relations are named for
James Clerk Maxwell, 1831–1879,
a great British physicist who made
fundamental contributions to
electromagnetic theory, gas kinetic
theory, and thermodynamics.
EXAMPLE 4.1
From the relation in Eq. (4.2-10), find an expression for (∂P/∂S)V,nfor an ideal gas with
constant heat capacity.
Solution
Equation (2.4-21) gives for a reversible adiabatic process in an ideal gas with constant heat
capacityTT 1(
V 1
V)nR/CVwhere we omit the subscripts on the final values ofTandV. Since a reversible adiabatic
process corresponds to constant entropy, differentiation of this formula with respect toV
corresponds to constantS:
(
∂P
∂S)V,nn−(
∂T
∂V)S,n−T 1 (V 1 )nR/CV(
nR
CV)
V−(nR/CV)−^1nR T 1
CVV(
V 1
V)
VnR/CVTo complete the solution, we replaceT 1 V 1 nR/CVbyTVnR/CV:
(
∂P
∂S)V,n−
nRT
CVV−
RT
CV, mVExercise 4.1
a.Find the value of (∂P/∂S)V,nfor 1.000 mol of helium at 1.000 atm (101325 Pa) and 298.15 K.
Assume that helium is ideal withCV 3 nR/2.
b.Find the value of (∂P/∂S)V,nfor 2.000 mol of helium at 1.000 atm (101325 Pa) and 298.15 K.
Explain the dependence on the amount of substance.
c.Find the value of (∂P/∂S)V,nfor 1.000 mol of helium at 2.000 atm (202650 Pa) and 298.15 K.
Explain the dependence on the pressure.We now write the differentialdHfor a closed system from the definition ofH:dHdU+PdV+VdPTdS−PdV+PdV+VdP (4.2-11)TdS+VdP (closed system)