STATEMENT-1 : Equivalent volume of `H_(2)` is 11.2 L at 1 atm and 273 K.
STATEMENT-2 : `1//2`mole `H_(2)` has produced when 1 mole of `H^(+)` (aq) accepted 1 mole of `e^(-)`.

STATEMENT -1 : 18 ml of H_(2)O and 18 ml of CO_(2) at 277 K have same no. of moles. and STATEMENT -2 : Density of H_(2)O is more than CO_(2) .

Volume of 0.5 mole of a gas at 1 atm. Pressure and 273 K is

1 mole of [OH^(-)] is present in how many moles of H_(2)O ?

The integral enthalpy of solution in kJ of one mole of H_(2)SO_(4) dissolved in n mole of water is given by : DeltaH_(s)=(75.6xxn)/(n+1.8) Calculate DeltaH for the following processes : (a) 1 mole of H_(2)SO_(4) dissolved in 2 mole of H_(2)O . (b) 1 mole of H_(2)SO_(4) dissolved in 7 mole of H_(2)O . (c ) 1 mole of H_(2)SO_(4) dissolved in 5 mole of H_(2)O . (d) solution (a) dissolved in 5 mole of H_(2)O . (e) 1 mole of H_(2)SO_(4) dissolved in excess of H_(2)O .

When 1 mole of PbS reacts completely with H_(2)O_(2)

When 1 mole of H_(2(g)) is heated with one mole of I_(2(g)), it was found that 1.48 moles of HI_((g)) is formed at equilibrium. Its K_c 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