The equilibrium constants `K_(p1)` and `K_(p2)` for the reactions X `hArr` 2Y and Z `hArr` P + Q, respectively, are in the ratio of `1:9` . If the degree of dissures at these equilibria is:

The equilibrium constant s K_(p1) and K_(p2) for the reactions X hArr 2 Y and Z hArr P + 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 pressures at these equilibria is

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_(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,

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,

The equilibrium constant K_(p1) and k_(p2) 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-