At a given temperature , total vapour pressure (in Torr) of a mixture of volatile components A and B is given by
`"P"_("total")=120-785"X"_("B")`
hence, vapour pressure of pure A and B respectively (in Torr) are

At a given temperature total vapour pressure (in torr) of a mixture of volatile compounds A and B given by P_("total")=120-75X_(B) . Hence, vapour pressure of pure A and B respectively (in torr) are

At a given temperature total vapour pressure (in Torr) of a mixture of volatile components A and B is given by P = 120 - 75 X_(B) hence vapour pressure of pure A and B respectively (in Torr) are

At a given temperature total vapour pressure (in Torr) of a mixture of volatile components A and B is given by P = 12 - 75 X_(B) hence vapour pressure of pure A and B respectively (in Torr) are

At a given temperature, total vapour pressure in Torr of a mixture of volatile components A and B is given by P = 120 - 75X_(B) hence vapour pressure ofpure A and B respectively ( in Torr) are :

At a given temperature, the vapour pressure in mm of Hg. of a solution of two volatile liquids A and B is given by the equation : rho = 120-80 X_(B) , X_(B) = mole fraction of B. Vapour pressures of pure A and B at the same temperature are respectively

The vapour pressure of a mixture of two volatile liquids is given by P_(M) = 4.0X_(A)+3.0 . Find the vapour pressure of pure B .

If the total vapour presure of the liquid mixture A and B is given by the equation: P=180X_(A)+90 then the ratio of the vapour pressure of the pure liquids A and B is given by :

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 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).