On mixing 1 mole of `C_(6)H_(6)(P^(@)=42mm)` and 2 mole of `C_(7)H_(8)(P^(@)=36mm)` one can conclude

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

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

Which of the following contains the largest mass of hydrogen atoms (a) 5.0 moles of C_(2)H_(2)O_(4) (b) 1.1 moles of C_(3)H_(8)O_(3) (c) 1.5 moles of C_(6)H_(8)O_(6) (d) 4.0 moles of C_(2)H_(4)O_(2)

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

From the mixture of 4 moles Ca_(3)(PO_(4))_(2) and 5 moles of P_(4) O_(10) and 6 moles of H_(3)PO_(3) all the phosphorus atoms are removed then moles of P_(4) molecule formed from all these atoms is

Order of increasing of entropy ammong given condition of substance is : (I) 1 mole of H_(2)O(I) at 298 K and 0.101 M pa (II) 1 mole of ice at 273 K and 0.101 M Pa (III) 1 mole of H_(2)(g) at 298 K and 1 atm (IV) 1 mole of C_(2)H_(6)(g) at 398 K abd 1 atm

At 334K the vapour pressure of benzene (C_(6)H_(6)) is 0.526 atm and that of toluene (C_(7)H_(8)) is 0.188 atm. In a solution containing 0.500 mole of benzene and 0.500 mole of toluene , what is the vapour pressure of toluene for above solution at 334K ?

Total vapour pressure of mixture of 1 mole of volatile component A (P_(A)^(@)=100 mm Hg) and 3 mole of volatile component B (P_(B)^(@)=80 mm Hg) is 90 mm Hg . For such case :

The total vapour pressure of a mixture of 1 mole of A ( P_A = 200 mm Hg ) and 3 mole of B ( P_B= 360 mm Hg) is 350 mm Hg. Then

C_(6)H_(5)CONHCH_(3) can be converted into C_(6)H_(5)CH_(2)NHCH_(3) by .