At certain temperature compound `AB_(2)(g)` dissociates accoring to the reacation
`2AB_(2)(g) hArr2AB (g)+B_(2)(g)`
With degree of dissociation `alpha` Which is small compared with unity, the expression of `K_(p)` in terms of `alpha` and initial pressure P is :

At temperature T, a compound AB_(2)(g) dissociates according to the reaction 2AB_(2)(g)hArr2AB(g)+B_(2)(g) with degree of dissociation alpha , which is small compared with unity. The expression for K_(p) in terms of alpha and the total pressure P_(T) is

At certain temp. compound AB_(2(g)) dissociate according to reaction AB_(2(g))hArrAB_(g)+B_(g) with degree of dissociation prop_(1) which is small compared with unity. The expression of K_(P) in terms of prop and initial pressure P is :-

At temperature ,T, a compound AB_2(g) dissociates according to the reaction 2AB_2 (g) ltimplies 2AB(g)+B_2(g) with a degree of dissociation, x, which is small compared with unity.Deduce the expression for K_P , in terms of x and the total pressure , P.

At temperature T, a compound AB_2(g) dissociation according to the reaction, 2AB _2(g) hArr 2AB(g) +B_2(g) with degree of dissociation, alpha , which is small compared to unity . Deduce the expression for alpha in terms of the equilibrium constant K_p and the total pressure P.

At a certain temperature T , a compound AB_(4)(g) dissociates as 2AB_(4)(g)hArrA_(2)(g)+4B_(2)(g) with a degree of dissociation alpha , which compared to unity. The expressio of K_(P) in terms of alpha and total pressure P is:

At a temperature T, a compound AB_4(g) dissociates as 2AB_4(g) hArr A_2(g)+4B_2(g) with a degree of dissociation x, which is small compared with unity. The expression of K_p in terms of x and total pressure P is :