The normal boiling point of water is 373 k. vapour of waterr at temperature T is 19 mm hg. If enthalpy of vapoursed is 40.67 kJ/mol, them temperature Twould be
(use : log 2 = 0.3, R : 8.3` Jk^(-1)mol^(-1)`):

The normal boiling point of watr is 373 K (at 760 mm), vapour pressure of water at 298 K is 23 mm. If entyalpy of vaporization is 40.656 kj//mol.the boiling point of water at 23 mm pressure will be :

At room temperature, a dilute solution of urea is prepared by dissolving 0.60 g of urea in 360 g of water. If the vapour pressure of pure water at this temperature is 35 mm Hg, lowering of vapour pressure will be: (molar mass of urea =60 g "mol"^(-1) )

The normal boiling point of toluene is 110.7^(@)C and its boiling point elevation constant 3.32 " K kg mol"^(-1) . The enthalpy of vaporization of toluene is nearly :

Find the mass of water vapour per cubic metre of air at temperature 300K and rekative humidity 50%. The saturation vapour pressure at 300K is 3.6kPa and the gas constant R=8.3JK^(-1)mol^(-1) .

The vapour pressure of water at room temperature is 23.8 mm Hg. The vapour pressure of an aqueous solution of sucrose with mole fraction 0.1 is equal to

Calculate the temperature of 4.0 mol of a gas occupying 5 dm^3 at 3.32 bar ( R = 0.083 " bar " dm^3 K^(-1)mol^(-1) ).

A solution containing 0.1 mol of naphthalene and 0.9 mol of benzene is cooled out until some benzene freezes out. The solution is then decanted off from the solid and warmed upto 353 K where its vapour pressure was found to be 670 mm . The freezing point and boiling point of benzene are 278.5 K and 353 K respectively, and its enthalpy of fusion is 10.67 KJ "mol"^(-1) . Calculate the temperature to which the solution was cooled originally and the amount of benzene that must have frozen out. Assume ideal behaviour.

Assuming that water vapour is an ideal gas, the internal energy change (Delta U) when 1 mol of water is vapourised at 1 bar pressure and 100^(@)C , (Given: Molar enthalpy of vapourization of water at 1 bar and 373K=41 kJ mol^(-1) and R=8.3J mol^(-1)K^(-1) ) will be:

Calculate the temperature of 4.0 mol of a gas occupying d dm^(3) at 3.32 bar. (R=0.083 bar dm^(3) K^(-1)mol^(-1)) .

If the enthalpy of vapourization of a liquid X is 30 kJ/mol and its entropy of Vaporization is 75 Jmol^-1K^-1 the temperature of vapours of liquid X at 1 atmosphere pressure is nearly