1 mol benzene `(P^(@)_("benzene")=42 mm)` and 2 mol toluence `(P^(@)_("toluene")=36 mm)` will have

If an ideal solution is made by mixing 2 moles of benzene (p^(@)=266mm) and 3 moles of another liquid (p^(@)=236 mm) . The total vapour pressure of the solution at the same temperature would be

Consider the following partially labelled figure (graph is upto scale) for an ideal binary solution of benzene and toluence and answer the following questions. p_("total") = p_("benzene") +p_("toluene") and p_("total") = p_("benzene")^(@) or p_("toluene")^(@) , are simultaneously valid for:

The mole fraction of toluene in the vapour phase which is in equilibrium with a solution of benzene (P_(B)^(@)=120 "torr") and toluene (P_(T)^(@)=80 "torr") having 2.0 mol of each, is

Total vapour pressure of mixture of 1 mol volatile component A(P^(@)A="100 mm Hg") and 3 mol of volatile component B(P^(@)B="60 mm Hg") is 75 mm. For such case -

Total vapour pressure of mixture of 1 mol of volatile component A(P_(A^(@))=100mmHg) and 3 mol of volatile component B(P_(B^(@)=60 mmHg) is 75mm . For such case:

Mole fraction of the toluene in the vapour phase which is in equilibrium with a solution of benzene ( p^(@) = 120 torr ) and toluene ( p^(@) =80 torr) having 2.0 mol of each is :

Total vapour pressure of mixture of 1 mol of volatile component A( p_(A)^(@)=100 mm Hg) and 3 mol of volatile component B( p_(B)^(@) =60 mm Hg) is 75 mm. For such case: