An ideal binary solution of two volatile compenents A and B are in equilibrium with atmospheric pressure at T kelvin. Find `(P_(A)^(@)+P_(B)^(@))` in atmosphere if the mole fraction of more volatille component in solution is `(1)/(2)`.

The vapor pressure 'P' in mmHg of a binary solution of two volatile components A and B at a certain temperature is represented by the equation P=245-101 chi where chi is the mole fraction of component A. The vapor pressures of the pure components A and B are____ respectively

An ideal solution has equal mol-fraction f two volatile components A and B .in the vapour above the solutions, the mol -fractions of A and B :

At a certain temperature pure liquid A and liquid B have vapour pressure 10 and 37 torr respectively. For a certain ideal solution of A and B , the vapours in equilibrium with the liquid has the components A and B in the partial pressure ratio P_(A):P_(B) = 1:7 . The mole fraction of A in the solution are:

Relative loweringof vapour pressure of a dilute solution is 0.2 . What is the mole fraction of non-volatile solute ?

An ideal solution has two components Aand B. If A is more volatile than B and also P_(A)^@ gt P_(T) , then the correct relation between mole fraction of A in liquid (X) and vapour (Y) phase is :

Mixture of volatile components A and B has total pressure ( in Torr ) p=265-130x_(A), where X_(A) is mole fraction of A in mixture . Hence P_(A)^(@)+P_(B)^(@)= ( in T o r r).

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)