CHAP. 3: FUNDAMENTALS OF THERMODYNAMICS [CONTENTS] 75
3.2.7 Fugacity coefficient
The fugacity/pressure ratio is called thefugacity coefficientφφ=f
p. (3.22)
U Main unit:dimensionless quantity.
Note:For an ideal gasφ= 1.Example
Knowing the values of the molar Gibbs energy of carbon dioxideGm(T, p) =−53 183J/mol at
T = 350 K andp= 10 MPa, andG◦m(T, pst) =−65 675. 14 J/mol, wherepst= 101.325 kPa,
calculate its fugacity and the fugacity coefficient at 350 K and 10 MPa.Solution
By substituting into the definition (3.21) we obtainf= 0. 101325 ×exp(
− 53183 −(− 65675 .14)
8. 314 × 350)
= 7.415 MPa, φ=7. 415
10
= 0. 7415.
3.2.8 Absolute and relative thermodynamic quantities
If a numerical value can be unambiguously assigned to a thermodynamic quantity of a system in
a given state, we say that the quantity is absolute. If a numerical value can be assigned only to
a change in a thermodynamic quantity during the system’s transition from one thermodynamic
state to another, we say that the quantity is relative.
Temperature, pressure, volume, amount of substance, fugacity, and heat capacities represent
typical absolute quantities. For these quantities there exist natural and universal (independent
of the substance) referential states. Such referential states are temperature 0 K, volume 0
m^3 , pressure or fugacity 0 Pa. Internal energy, enthalpy, the Helmholtz energy and the Gibbs
energy represent typical relative quantities. There do not exist any universal referential states
for these quantities.