Mole Fraction

Statement-1 : The mass fraction of solute in a solution is always greater than its mole fraction Statement-2 : Mole fraction of solvent in an aqueous solution of ethanol must be greater than that of solute

For an binary mixture of A and B with p_(A)^(0)ltp_(B)^(0) : x_(A)= mole fraction of A in solution x_(B)= mole fraction of B in solution y_(A)= mole fraction of A in vapour phase y_(B)= mole fraction of B in vapour phase solution

Assertion: The weight percentage of a compound A in a solution is given by % of A=("Mass A")/("Total mass of solution")xx100 Reason: The mole fraction of a component A is given by, Mole fraction of A =("No. of moles of A")/("Total no. of moles of all components")

At a certain temperature, the vapour pressure of pure ether is 640 mm and that of pure acetone is 280 mm . Calculate the mole fraction of each component in the vapour state if the mole fraction of ether in the solution is 0.50.

A solution of urea received from some research laboratory has been marked mole fraction (x) and molality (m) at '10^@C'. While calculating its molality and mole fraction in the laboratory at '24^@C', you will find

Liquid 'M' and liquid 'N' form an ideal solution. The vapour pressures of pure liquids 'M' and 'N' are 450 and 700 mmHg, respectively, at the same temperature. Then correct statement is : (x_(M) = Mole fraction of 'M' in solution, x_(N) = Mole fraction of 'N' in solution , y_(M) = Mole fraction of 'M' in vapour phase , y_(N) = Mole fraction of 'N' in vapour phase)

Liquid ‘M’ and liquid ‘N’ form an ideal solution. The vapour pressures of pure liquids ‘M’ and ‘N’ are 450 and 700 mmHg, respectively, at the same temperature. Then correct statement is: ( x_(M)= Mole fraction of ‘M’ in solutions , " " x_(N)= Mole fraction of ‘N’ in solution , y_(M)= Mole fraction of ‘M’ in vapour phase , " " y_(N)= Mole fraction of ‘n’ in vapour phase)