CHAPTER 8 PHASE TRANSITIONS AND EQUILIBRIA OF PURE SUBSTANCES
8.2 PHASEDIAGRAMS OFPURESUBSTANCES 207
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bc bc bc bc ut
bc rs02004006008001000270 280 290 300 310
T=K=kg m�^3(a)ut
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T=K=kg m�^3(b)Figure 8.8 Densities of coexisting gas and liquid phases close to the critical point
as functions of temperature for (a) CO 2 ;a(b) SF 6 .b Experimental gas densities are
shown by open squares and experimental liquid densities by open triangles. The mean
density at each experimental temperature is shown by an open circle. The open dia-
mond is at the critical temperature and critical density.
aBased on data in Ref. [ 116 ].
bData of Ref. [ 127 ], Table VII.Tandp, the system point moves to point B at the right end of the tie line.V=nat this point
must be the same as the molar volume of the gas,Vmg. We can see this because the system
point could have moved from within the one-phase gas area to this position on the boundary
without undergoing a phase transition.
When, on the other hand, enough heat is transferred out of the system to condense all
of the gas, the system point moves to point A at the left end of the tie line.V=nat this point
is the molar volume of the liquid,Vml.
When the system point is at position S on the tie line, both liquid and gas are present.
Their amounts must be such that the total volume is the sum of the volumes of the individual
phases, and the total amount is the sum of the amounts in the two phases:
V DVlCVgDnlVmlCngVmg (8.2.1)nDnlCng (8.2.2)The value ofV=nat the system point is then given by the equation
V
nD
nlVmlCngVmg
nlCng