180 4 The Thermodynamics of Real Systems
Exercise 4.13
a.At 373.15 K and 1.000 atm, the Gibbs energy change of vaporization of water is equal to
zero, and the entropy change is equal to 109 J K−^1 mol−^1. Find the Gibbs energy change of
vaporization of superheated water at 378.15 K and 1.000 atm, using Eq. (4.4-18). What does
the sign of your answer mean?
b.Repeat the calculation of part a using Eq. (4.4-19). Assume that∆His constant and
equal to 40.67 kJ mol−^1. Comment on the comparison between your values for parts a
and b.
PROBLEMS
Section 4.4: Gibbs Energy Calculations
4.28 a.Find the value of∆Gfor 1.000 mol of an ideal gas
if it is isothermally pressurized from 1.000 atm to
3.000 atm at 298.15 K.
b.Find the value of∆Gfor 1.000 mol of an ideal gas
if it is isothermally pressurized from 2.000 atm to
4.000 atm at 298.15 K.
c.Explain in words why your answers for parts a and b
are not equal although the changes in pressure are
equal.
4.29 2.000 mol of helium gas (assume ideal) expands
isothermally and irreversibly at a constant external
pressure of 1.000 atm and a temperature of 298.15 K
from a volume of 10.00 L to a volume of 40.00 L.
a.Findq,w,∆U,∆S,∆Ssurr,∆H,∆A, and∆G.
b.Findq,w,∆U,∆S,∆Ssurr,∆H,∆A, and∆Gif
the process is carried out reversibly at the same
temperature.
4.30 a.Find the value of∆Gif 1.000 mol of liquid
water is pressurized at 0.00◦C from 1.000 atm to
50.000 atm. Assume that the liquid water has a fixed
volume.
b.Find the value of∆Gif 1.000 mol of solid water is
pressurized at 0.00◦C from 1.000 atm to 50.000 atm.
Assume that the solid water has a fixed volume.
c.Find the value of∆Gif 1.000 mol of solid water (ice)
melts at 0.00◦C and 1.000 atm.
d.Find the value of∆Gif 1.000 mol of solid water melts
at 0.00◦C and 50.000 atm. What does the sign of your
answer indicate?
4.31 a.Write an expression for∆Afor the isothermal
expansion of an ideal gas from volumeV 1 to
volumeV 2.
b. Find the value of∆Afor each of the processes in
parts a and b of Problem 4.28. Explain the relationship
of these values to the values of∆Gfor the same
processes.
4.32 a.At 273.15 K and 1.000 atm, the Gibbs energy change
of fusion of water is equal to zero, and the enthalpy
change is equal to 6008 J mol−^1. Find the Gibbs
energy change of fusion of water at 263.15 K and
1.000 atm, using Eq. (4.4-18). What does the sign of
your answer mean?
b. Repeat the calculation of part a using Eq. (4.4-20).
Comment on the comparison between your values for
parts a and b.
4.33 Consider a gas obeying the truncated virial equation
of state
PVm
RT
1 +
B 2
Vm
+
B 3
Vm^2
a.Write an expression for∆Afor the isothermal
expansion from volumeV 1 to volumeV 2 fornmoles
of this gas.
b.Find the value of∆Afor the isothermal expansion of
1.000 mol of argon at 298.15 K from a volume of
10.000 L to a volume of 25.000 L, assuming that
B 3 ≈0. Compare with the result assuming argon to be
an ideal gas.
c.Manipulate the van der Waals equation of state into the
form of the virial equation of state and show that