For the mixture of liquid "A" `(P^(0)=40mm ` of Hg) and liquid "B" (`P^(0)=72mm` of Hg), the vapour pressure is found to be 56mm of Hg. Assuming ideal behaviour of the solution

Two moles of pure liquid 'A' (P_(A)^(0)=80 mmof Hg) and 3 mole of pure liquid 'B' (P_(B)^(0)=120mm of Hg) are mixed . Assuming ideal behaviour

4 mole of pure liquid A (P_(A)^(0)=80mm of Hg) and 6 mole of pure liquid B (P_(B)^(0)=100mm of Hg) are mixed . The vapour pressure of the resulting solution is found to be 90 mm of Hg then

The vapour pressure of a pure liquid A is 40 mm of Hg at 310K. The vapour pressure of its liquid in a solution with liquid B is 32 mm of Hg. Mole fraction of A in the solution, if it obeys Raoult's law is :

At certain temperature a solution of 3 mol of a liquid A(P^(0)=500 torr) and 1 mol of liquide B(P^(0)=340 torr) has a vapour pressure of 435 torr , we can conclude that

The vapour pressure of a mixure of 1 mole of liquid 'A' and 3 mole of liquid 'B' is 550 mm of Hg. When one mole of liquid 'B' is further added, the vapour pressure of the solution increases by 10 mm of Hg. The vapour pressure of pure liquid A and B are respectively in mm of Hg .

One mole of liquid A (vapour pressure =300 mm Hg ) and 2 moles of a liquid B (Vapour pressure =360 mm Hg) are mixed . The mole fraction of A in the vapour mixture if found to be 5//17 . Which of the following is correct ?

The normal blood pressure in man is 120/80 mm of Hg. What does 120 in this valve represent?

A vessel contains a mixture of equal weights of oxygen and SO_2 at a pressure of 600mm of Hg. The partial pressure of oxygen in mm is

When some amount of non-volatile solute is dissolved in a solvent to prepare a dilute solution, the vapour pressure of the solvent is lowered and it is directly proportional to the mole fraction of solvent in the solution . Relative lowering in vapour pressure is equal to mole fraction of solute . Elevation in boiling point of solvent is a collgative property like lowering in vaour pressure of solvent in solution , K_(b) i.e., molal elevation constant is calculated by the formula, K_(b)=DeltaT_(b)// molality and also by the expression, K_(b)=RT_(b)^(2)//1000l_(v) where T_(b) is boiling point of solvent and I_(v) is latent heat of vapourisation for 1 gm solvent . Abnormal elevation is boiling point =iX elevation in boiling point in ideal solution where i=van't Hoff factor Lowering in vapour pressure in an experiment was found to be x mm of Hg. It is : Lowering in vapour pressure in an experiment was found to be x mm of Hg. It is