184 4 The Thermodynamics of Real Systems
so that the natural independent variables forAareT,V,n 1 ,n 2 ,...,nc. By inspectionμi(
∂U
∂ni)
S,V,n′(4.5-10)
andμi(
∂A
∂ni)
T,V,n′(4.5-11)
Exercise 4.14
Derive Eqs. (4.5-8) and (4.5-9).The chemical potential is equal to four different partial derivatives with different
variables held fixed. The partial derivative in Eq. (4.5-4) identifies the chemical poten-
tial as thepartial molar Gibbs energy. A generalpartial molar quantityis a partial
derivative of an extensive quantity with respect to the amount of one component, keep-
ingT,P, and the amounts of all other components fixed. If the letterYstands for
any extensive quantity (U,H,A,G,S,V, and so on),the partial molar quantity for
substance numberi is denoted byYiand defined byYi(
∂Y
∂ni)
T,P,n′(4.5-12)
The chemical potentialμi is equal toGi. The partial derivatives in Eqs. (4.5-7),
(4.5-10), and (4.5-11) to whichμiis equal are not partial molar quantities, because
PandTare not both held fixed in the differentiations.EXAMPLE4.18
Find a relationship between the chemical potential and the partial molar enthalpy.
Solution
We begin with the relationship betweenGandH:GH−TSDifferentiation of both sides at constantT,P, andn′gives
(
∂G
∂ni)T,P,n′(
∂H
∂ni)T,P,n′−T(
∂S
∂ni)T,P,n′orμiHi−TSi