700 | Thermodynamics
of the pure component. Many liquid solutions encountered in practice, espe-
cially dilute ones, satisfy this condition very closely and can be considered to
be ideal solutions with negligible error. As expected, the ideal solution
approximation greatly simplifies the thermodynamic analysis of mixtures. In
an ideal solution, a molecule treats the molecules of all components in the
mixture the same way—no extra attraction or repulsion for the molecules of
other components. This is usually the case for mixtures of similar substances
such as those of petroleum products. Very dissimilar substances such as
water and oil won’t even mix at all to form a solution.
For an ideal-gas mixture at temperature Tand total pressure P, the partial
molar volume of a component iis viviRuT/P. Substituting this relation
into Eq. 13–41 gives
(13–42)
since, from Dalton’s law of additive pressures,PiyiPfor an ideal gas
mixture and
(13–43)
for constant yi. Integrating Eq. 13–42 at constant temperature from the total
mixture pressure Pto the component pressure Piof component igives
(13–44)
For yi1 (i.e., a pure substance of component ialone), the last term in the
above equation drops out and we end up with mi(T,Pi) mi(T,P), which is
the value for the pure substance i. Therefore, the term mi(T,P) is simply the
chemical potential of the pure substance iwhen it exists alone at total mix-
ture pressure and temperature, which is equivalent to the Gibbs function
since the chemical potential and the Gibbs function are identical for pure
substances. The term mi(T,P) is independent of mixture composition and
mole fractions, and its value can be determined from the property tables of
pure substances. Then Eq. 13–44 can be rewritten more explicitly as
(13–45)
Note that the chemical potential of a component of an ideal gas mixture
depends on the mole fraction of the components as well as the mixture tem-
perature and pressure, and is independent of the identity of the other con-
stituent gases. This is not surprising since the molecules of an ideal gas
behave like they exist alone and are not influenced by the presence of other
molecules.
Eq. 13–45 is developed for an ideal-gas mixture, but it is also applicable to
mixtures or solutions that behave the same way—that is, mixtures or solutions
in which the effects of molecules of different components on each other are
negligible. The class of such mixtures is called ideal solutions(or ideal mix-
tures), as discussed before. The ideal-gas mixture described is just one cate-
mi,mixture,ideal 1 T, Pi 2 mi,pure 1 T, P 2 RuT ln yi
mi 1 T, Pi 2 mi 1 T, P 2 RuT ln
Pi
P
mi 1 T, P 2 RuT ln yi¬¬ 1 ideal gas 2
d ln Pid ln 1 yiP 2 d 1 ln yiln P 2 d ln P¬¬ 1 yiconstant 2
dmi
RuT
P
dPRuTd ln PRuTd ln Pi 1 Tconstant, yiconstant, ideal gas 2