4.6 Euler’s Theorem and the Gibbs–Duhem Relation 189
kwith independent variablesn 1 ,n 2 ,...,nc,Euler’s theoremstates that
kf
∑c
i 1
ni
(
∂f
∂ni
)
n′
(Euler’s theorem) (4.6-2)
where the subscriptn′stands for holding all of then’s constant except forni. A proof
of this theorem is found in Appendix D.
LetYstand for any extensive quantity. SinceYis homogeneous of degree 1 in the
n’s ifTandPare constant, Euler’s theorem becomes
Y
∑c
i 1
ni
(
∂Y
∂ni
)
T,P,n′
∑c
i 1
niYi (4.6-3)
whereYiis the partial molar quantity for substanceiand wherecis the number of
components. Remember thatTandPare held constant in the differentiations of the
partial molar quantities. Two important examples of Eq. (4.6-3) are
G
∑c
i 1
niμi (4.6-4)
and
V
∑c
i 1
niVi (4.6-5)
Equation (4.6-3) is a remarkable relation that gives the value of an extensive quantity
as a weighted sum of partial derivatives. An unbiased newcomer to thermodynamics
would likely not believe this equation without its mathematical proof.
Euler’s theorem can also be written in terms of themean molar quantityYm, defined
byYmY/n, wherenis the total amount of all components:
Ym
1
n
∑c
i 1
niYi
∑c
i 1
xiYi (4.6-6)
wherexiis themole fractionof substance numberi, equal toni/n.
EXAMPLE4.21
In a solution of acetone (component 1) and chloroform (component 2)x 1 0 .531 and
V 1 74 .2cm^3 mol−^1 .IfVm77.0 cm^3 mol−^1 at this composition, findV 2.
Solution
From Euler’s theorem
V 2
Vm−x 1 V 1
x 2
77 .0cm^3 mol−^1 −( 0. 531 )
(
74 .2cm^3 mol−^1
)
0. 469
80 .2cm^3 mol−^1