Answer:
2.8
Step-by-step explanation:
Dalton´s law of partial pressures tell us that for a binary mixture:
Ptot = Pa + Pb, and
Pa = Xa Pºa where Pa is the partial vapor pressure of companent A above the solution
Now the gas phase which is formed will have a composition given by :
Ptot = Pa + Pb where Ptot is the total vapor pressure for the components A and B
So lets calculate the partial vapor pressures in the mixture:
P(C7H16) = 0.50 x 31 torr = 15.5 torr
P(C8H18) = 0.50 x 11 torr = 5.5 torr
Ptot = 15.5 torr + 5.5 torr = 21 torr
Now the composition of the vapor pressure will obey the relation:
γ (C7H16) = P(C7H16) / Ptot where γ is the mol fraction of C7H16 in the vapor. (Note use γ to refer to mol fraction in the vapor to differentiate it from Xa which is the mol fraction in the liquid)
Plugging our values:
γ (C7H16) = 15.5 torr/ 21 torr = 0.74
and since γ (C7H16) + γ (C8H18) = 1, we have
γ (C8H18) = 1 - 0.74 = 0.26
which is correct: the mol fraction of the more volatile C7H16 should be greater than C8H18.
So the mole ratio of heptane to octane will be given by the ratio:
0.74/ 0.26 = 2.8
which is correct since the mole ratio of heptane to octane should be greater than one since the vapor is richer in the more volatile C7H16 (almost 3 to 1 which is in the same ratio as the pure vapor pressures)