The values of `K_(p_1) and K_(P_2)` for the reactions
`X hArr Y+Z` ………..(i)
`A hArr 2B` …………..(ii)
are in ratio of `9:1` if degree of dissociation X and A be equal then total pressure at equilibrium (i) and (ii) are in the ratio

The values of K_(p_(1)) and K_(p_(2)) for the reactions X hArr Y+Z ….(i) and A hArr 2B …(ii) are in ratio of 9 : 1. If degree of dissociation of X and A be equal, then total presure at equilibrium (i) and (ii) are in the ratio.

For the reaction (1)and(2) A(g)hArrB(g)+C(g) X(g) hArr2Y(g) Given , K_(p1):K_(p2)=9:1 If the degree of dissociation of A(g) and X(g) be same then the total pressure at equilibrium (1) and (2) are in the ratio:

The equilibrium constant K_(p_(1)) and K_(p_(2)) for the reactions XhArr2Y and ZhArrP+Q , respectively are in the ratio of 1:9 . If the degree of dissociation of X and Z be equal, then the ratio of total pressure at these equilibrium is:

The equilibrium constant K_(p_(2)) and K_(p_(2)) for the reactions A hArr 2B and P hArr Q+R , respectively, are in the ratio of 2:3 . If the degree of dissociation of A and P are equal, the ratio of the total pressure at equilibrium is,

K_(p)//K_(c) for the reaction CO(g)+1/2 O_(2)(g) hArr CO_(2)(g) is

K_(p)//K_(c) for the reaction CO(g)+1/2 O_(2)(g) hArr CO_(2)(g) is

K_(p) for the reaction A hArr B is 4. If initially only A is present then what will be the partial pressure of B after equilibrium ?

In the reaction AB(g) hArr A(g) + B(g) at 30^(@)C, k_(p) for the dissociation equilibrium is 2.56xx10^(-2) atm . If the total pressure at equilibrium is 1 atm, then the percentage dissociation of AB is

An equilibrium PCl_5(g) dissociate 50% ,then the value of (P +K_p) is (where P = total pressure at equilibrium)

For the reaction N_(2)O_(4)(g)hArr2NO_(2)(g) , the degree of dissociation at equilibrium is 0.2 at 1 atm pressure. The equilibrium constant K_(p) will be