The dissociation equilibrium of a gas `AB_(2)` can be represented as
`2AB_(2)(g)hArr 2AB(g)+B_(2)(g)`
The degree of dissociation is x and is small compared to 1. The expression relating the degree of dissociation (x) with equilibrium contant `K_(p)` and total pressure p is

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 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 dissociation equilibrium of a gas AB, can be represented as The degree of dissociation is x and is small compared to 1. The expression relating the degree of dissociation (x) with equilibrium constant K,, and total pressure p is (a) (2K_(p)//p) (b) (2K_(p)//p)^(1//3) (c) (2K_(p)//p)^(1//2) (c) (K_(p)//p)

The dissociation equilibrium of a gas AB, can be represented as The degree of dissociation is x and is small compared to 1. The expression relating the degree of dissociation (x) with equilibrium constant K,, and total pressure p is

The dissociation equilibrium of AB_(2) gas is, 2AB_(2)(g) hArr 2AB(g)+B_(2)(g) The degree of dissociation of AB_(2)(g) is x and x lt lt 1 . Establish the relation among the degree of dissociation (x), equilibrium constant (K_(p)) and total pressure (P).