At `444^(@) C`, the equilibrium constant K for the reaction `2AB_((g))hArrA_(2(g)) + B_(2(g))` is `1/64` . The degree of dissociation of AB will be -

The factor which changes equilibrium constant of the reaction A_(2)(g)+B_(2)(g) rarr 2AB(g) is

2 is the equilibrium constant for the reaction A_(2)+B_(2)hArr 2AB at a given temperature. What is the degree of dissociation for A_(2)" or "B_(2)

For the reaction AB_(2)(g)hArrAB(g)+B(g) If prop is negligiable w.r.t 1 then degree of dissociaation (prop) of AB_(2) is proportional to :

The answer to each of the folowing questions is a single digit integar, ranging from 0 to 9. If the correct answers to the question numbers A, B, C and D (say) are 4,0,9 and 2 respectively , then the correct darkening of bubbles should be as shown on the side : Equilibrium constant for the reaction A_(3) (g) + 3 B_(2) (g) hArr 3 AB_(2) (g) " is " 64*0 "Then the equilibrium constant for the reaction " 1/3 A_(3) (g) + B_(2) (g) hArr AB_(2)(g) will be

The dissociation equilibrium of a gas AB_2 can be represented as, 2AB_2(g) hArr 2AB (g) +B_2(g) . The degree of disssociation is 'x' and is small compared to 1. The expression relating the degree of dissociation (x) with equilibrium constant k_p and total pressure P is

The equilibrium constant for the reaction A_(2)(g)+B_(2)(g) hArr 2AB(g) is 20 at 500K . The equilibrium constant for the reaction 2AB(g) hArr A_(2)(g)+B_(2)(g) would be