`P_(A)=(235y -125xy)mm` of `HgP_(A)` is partial pressure of `A,x` is mole fraction of B in liquid phase in the mixture of two liquids A and B and y is the mole fraction of A in vapour phase, then `P_(B)^(@)` in mm of Hg is:

Mixture of two liquids A and B is placed in cylinder containing piston. Piston is pulled out isotehrmally so that volume of liquid decreases but that of vapour increases. When negligibly small amount of liquid was remaining the mole fraction of A in vapour is 0.4 . Given P_(A)^(@) = 0.4 atm and P_(B)^(@) = 1.2 atm at the experimental temperature. Calculate the total pressure at whcih the liquid has almost evaporated. (Assume ideal behaviour)

If P^(@) the vapour pressure of a pure solvent and P is the vapour pressure of the solution prepared by dissolving a non volatile solute in it. The mole fraction of the solvent X_(A) is given by:

Two points A and B are at same depth in arest liquid . Then pressure on them P_(A)…….P_(B) .

Mixture of volatile components A and B has a total vapour pressure (in torr)p= 254-119 x_(A) is where x_(A) mole fraction of A in mixture .Hence P_(A)^@ and P_(B)^@ are(in torr)

If a,b,c are in G.P and A.M of a and b is x and A.M. of b and c is y then…….

10 mole of liquid 'A' and 20 mole of liquid 'B' is mixed in a cylindrical vessel containing a piston arrangement. Initially a pressure of 2 atm is maintained on the solution. Now, the piston is raised slowely and isothermally. Assume ideal behaviour of solution and A and B are completely miscible. P_(A)^(@) = 0.6 atm and P_(B)^(@) = 0.9 atm The pressure below which the evaporation of liquid solution will start, is