The equilibrium constant `K_(p_(1)) and K_(p_(2))` for the reaction `XhArr 2Y and Z hArrP+Q`, respectively are in the ratio of 1:9. if the degree of dissociation of X and Z be equal, find the ratio of total pressure at these equilibriam.

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-

If the investments are in the ratio x : y : z and the profit in the ratio P : Q : R, then the ratio of periods of the investments is____

If the equilibrium constants of following reactions are 2A hArr B is K_(1) and B hArr2A is K_(2) , then

If the ratio of the roots of the equation x^2-px+q=0 be 1:2 , find the relation between p and q.

At a given temperature, the reaction, A(g)hArr 2N(g) , is in equilibrium in a closed flask. At the same temperature, the reaction c(g)hArr D(g)+E(g) is in equilibrium in an another closed flask. Values of equilibrium constants of these two reactions are K_(p1) and K_(p2) respectively and the total pressures of the equilibrium mixtures are P_1 and P_2 respectively. If K_(p1) : K_(p2) = 1 : 4 and P_1 : P_2 = 1 : 4 then the ratio of degree of dissociation of A(g) and C(g) are ( assume the degrees of dissociation of both are very small compared to 1)-

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).

The equilibrium constant (K_P) for the decomposition of gaseous H_2O, H_2O(g)toH_2(g)+1/2O_2(g) , is related to degree of dissociation (prop) at a total pressure ( P) as-

An equilibrium reaction is endothermic if K_(1) and K_(2) are the equilibrium constants at T_(1) and T_(2) temperatures respectively and if T_(2) is greater than T_(1) then

For the reaction (1) and (2) A(g) iff B(g)+C(g) .....(1) X(g) iff 2Y(g) ....(2) Given, K_(p_1):K_(p_2) = 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 :