For an ideal liquid solution with `P_A^(@)gtP_B^(@)`, which relation between` X_(A)` ((mole fraction of A in liquid phase) and `Y_(A)`(mole fraction of A in vapour phase) is correct ?

If two substances A and B have p_A^0 : p_B^0 = 1: 2 and have mole fraction in solution 1: 2, then mole fraction of A in vapours is

Two liquids A and B have vapour pressure in the ratio P_(A)^(0):P_(B)^(0)=1:3 at a certain temperature . Assume A and B from an ideal solution and the ratio of mole fraction of A to B in the vapour phase is 4:3 . Then the mole fraction of B in the solution at the same temperature is :

An ideal solution of hexane and heptane at 30^(@)C has a vapour pressure of 95 bar with hexane mole fraction 0.305. in vapour phase hexane mole fraction is 0.555. The vapour pressure of pure hexane and heptane at 30^(@)C respectively in bar are

If two substance A and B have P_A: P_B=1 : 2 and also X_A : X_B in solutions as 1 : 2, then mole fraction of A in vapours is

Two liquids A and B with vapour pressures 400mm Hg and 600mm Hg respectively formed a binary ideal liquid mixure shown in the following diagram . (Temepature =constant) If the mole fraction of 'A' in the vapour phase is 0.5 , What is the optimum pressure , above which the vapour phase can start condensig back into liquid.

For an ideal solution of two components A and B, If x_A and y_A are mole fractions of component 'A' in solution and vapour phase respectively, then the slope of linear line in the graph drawn between 1//x_A and 1//y_A is

At 300 K an ideal solution is formed by mixing 460 g of toluene with 390 k benzene. If the vapour pressure of pure toluene and respectively the mole fraction of toluene in vapour phase is

Give the relation between the partial pressure of a gas and its mole fraction.