Answer:
Composition of the mixture:
[tex]x_{A} =0.652=65.2[/tex] %
[tex]x_{B} =0.348=34.8[/tex] %
Composition of the vapor mixture:
[tex]y_{A} =0.809=80.9[/tex]%
[tex]y_{B} =0.191=19.1[/tex]%
Explanation:
If the ideal solution model is assumed, and the vapor phase is modeled as an ideal gas, the vapor pressure of a binary mixture with [tex]x_{A}[/tex] and [tex]x_{B}[/tex] molar fractions can be calculated as:
[tex]P_{vap}=x_{A}P_{A}+x_{B}P_{B}[/tex]
Where [tex]P_{A}[/tex] and [tex]P_{B}[/tex] are the vapor pressures of the pure compounds. A substance boils when its vapor pressure is equal to the pressure under it is; so it boils when [tex]P_{vap}=P[/tex]. When the pressure is 0.60 atm, the vapor pressure has to be the same if the mixture is boiling, so:
[tex]0.60*760=P_{vap}=x_{A}P_{A}+x_{B}P_{B}\\456=x_{A}P_{A}+(1-x_{A})P_{B}\\456=x_{A}*(P_{A}-P_{B})+P_{B}\\\frac{456-P_{B}}{P_{A}-P_{B}}=x_{A}\\\\\frac{456-250}{566-250}=x_{A}=0.652[/tex]
With the same assumptions, the vapor mixture may obey to the equation:
[tex]x_{A}P_{A}=y_{A}P[/tex], where P is the total pressure and y is the fraction in the vapor phase, so:
[tex]y_{A} =\frac{x_{A}P_{A}}{P}=\frac{0.652*566}{456} =0.809=80.9[/tex] %
The fractions of B can be calculated according to the fact that the sum of the molar fractions is equal to 1.
