176 4 The Thermodynamics of Real Systems
Solution
Let 1 atm be denoted byP◦atmwith a similar symbol for the 1-atm standard-state molar
Gibbs energies. We writeGm(T,P)G◦m(T)+RTln (P/P◦)
G◦m(T)+RTln (P◦atm/P◦)+RTln (P/P◦atm)This equation has the correct form ifG◦matmG◦m(T)+RTln (P◦atm/P◦)
G◦m(T)+RTln (1.01325)
G◦m(T)+(0.013 16)RTAt 298.15 K,G◦matm−G◦m(T) 32 .16 J mol−^1 0 .03216 kJ mol−^1The Gibbs Energy of a Real Gas. Fugacity
When a gas requires corrections for nonideality we write a new equation in the same
form as Eq. (4.4-5), replacing the pressure by thefugacity,f, which has the dimensions
of pressure:Gm(T,P)G◦m(T)+RTln(
f
P◦)
(definition of the fugacityf) (4.4-6)The fugacity plays the same role in determining the molar Gibbs energy of a real gas as
does the pressure in determining the molar Gibbs energy of an ideal gas. The quantity
G◦m(T) is the molar Gibbs energy of the gas in its standard state. The standard state of
a real gas is defined to be the corresponding ideal gas at pressureP◦. We can obtain an
expression for the molar Gibbs energy of a real gas as follows:Gm,real(T,P′)−G◦m(T)Gm,real(T,P′)
− lim
P′′→ 0[
Gm,real(T,P′′)−Gm,ideal(T,P′′)]
−G◦m(T)
(4.4-7)where we have added two terms that cancel because the real gas and the corresponding
ideal gas become identical in the limit of zero pressure. From Eq. (4.4-1), the first two
terms on the right-hand side of Eq. (4.4-7) represent∆Gfor changing the pressure of
the real gas from 0 toP′at constant temperature:(first two terms)∫P′
0Vm,realdP (4.4-8)From Eq. (4.4-3), the last two terms in the right-hand side of Eq. (4.4-7) are equal to(last two terms)∫ 0
P◦Vm,idealdP∫ 0
P◦RT
P
dP (4.4-9)