An equilibrium mixture for the reaction, `2H_(2)S(g) hArr 2H_(2) (g) + S_(2) (g)` has 1 mole of `H_(2)`S, 0.2 mole of `H_(2)` and 0.8 mole of `S_(2)` in 2 L flask . The value of `K_(C)` in mol `L^(-1)` is

The equilibrium constant for the reaction , H_(2) (g) + CO_(2) (g) hArr H_(2) O (g) + CO (g) is 16 at 1000^(@) C . If 1.0 mole of H_(2) and 1.0 mole of CO_(2) are placed in one litre flask , the final equilibrium concentration of CO at 1000^(@) C is

The value of K_(p) for the reaction 2H_(2)S(g) hArr 2H_(2)(g) +S_(2)(g) is 1.2 xx 10^(-2) at 1065^(circ)C . The value of K, for this reaction is

At a given temperature, Ke is 4 for the reaction H_(2(g)) + CO_(2(g)) hArr H_(2)O_((g)) + CO_((g)) . Initially 0.6 moles each of H_(2) and CO_(2) are taken in 1lit flask. The equilibrium concentration of H_(2) O_((g)) is

A reaction S_((g)) hArr 4S_(2(g)) is s carried out by taking 2 moles of S_(8(g)) and 0.2 mole of S_(2(g)) in a reaction vessel of l lit. Which one is not correct. If K_(c) = 6.3 xx 10^(-6) .

The equilibrium constant K_(c) for the reaction P_(4(g)) hArr 2P_(2(g)) is 1.4 at 400^(@) C. Suppose that 3 moles of P_(4(g)) and 2 moles of P_(2(g)) are mixed in 2 litre container at 400^(@) C. What is the value of reaction quotient (Q_(c)) ?

Consider the following reaction equilibrium N_(2)(g)+ 3H_(2)(g) hArr 2NH_(3) Initially, 1 mole of N_(2) and 3 moles of H_(2) are taken in a 2 2L flask. At equilibrium state, if the number of moles of N_(2) is 0.6, what is the total number of moles of all gases present in the flask?

If the equilibrium constant for the reaction, H_(2)(g) +I_(2)(g) hArr 2HI(g) is K What is the equilibrium constant of HI(g) rarr 1/2 H_(2)(g) + 1/2I_(2)(g) ?

The enthalpy of the reaction H _(2 (g)) + 1/2 O _(2(g)) to H _(2) O _((g)) is Delta H _(1) and that of H _(2(g)) + 1/2 O _(2(g)) to H _(2) O _((l)) is Delta H _(2). Then