c09 JWBS043-Rogers September 13, 2010 11:26 Printer Name: Yet to Come
TWO-COMPONENT PHASE DIAGRAMS 135
The mole fraction of a two-component system runs from 0 to 1.0 (Fig. 9.4) wherenB
is the number of moles of component B andnA+nBis the total number of moles of
both components.
9.6.1 Type 1
In a two-component one-phase Type I diagram, pressure is taken as constant. Setting
p=const reduces the number of degrees of freedom by 1: f= 3 −P=2for
1 phase. (Please do not confusepandP.) The system can be represented in two
dimensions as in Fig. 9.8. If one phase is present, the system can exist at a temperature
and mole fraction represented by any point(T,XB)in either area above or below the
coexistance curves. The upper and lower curves represent the locus of mole fractions
of the vapor (upper) and liquid (lower), respectively, in equilibrium with one another
at a temperature specified on the vertical axis. A system at any temperature and mole
fraction between the coexistence curves splits into two phases, a vapor (upper curve)
and a liquid (lower curve).
When there are two phases in equilibrium (liquid and vapor), the number of
degrees of freedom is further reduced (f= 3 −P= 3 − 2 =1); and specifyingXB
of the system, as the mole fraction in the liquid phase or the mole fraction in the
vapor, automatically specifies the temperature on one of the two coexistence curves.
These two temperatures will not be the same. The lower curve in Fig. 9.8 is the locus
of points at which a trace of vapor is in equilibrium with liquid. The upper curve in
Fig. 9.8 is the locus of points at which a trace of liquid is in equilibrium with vapor.
The horizontal lines connecting them represent thel→vorv→lphase change at
any specific temperature,T(K).
Fractional distillation is one of our most important laboratory and industrial meth-
ods of chemical purification. The separation between the upper and lower curves in
a Type I diagram makes fractional distillation possible. At any temperature, the mole
fraction of component B in the mixture can be read along the horizontal in Fig. 9.8.
As seen from the figure, the mole fractions are different for coexisting liquid and
vapor phases except at the end points of the curves. If we allow a liquid mixture of
XB
T (K)
FIGURE 9.8 A Type I phase diagram. Liquid–vapor equilibriums are expressed by each of
the three horizontal lines.