In the equilibrium constant for `AhArr B+C` is `K_(eq)^((1))` and that of `B+C=P` is `K_(eq)^((2))`, the equilibrium constant for `AhArr P` is :

At equilibrium, the value of equilibrium constant K is

The equilibrium constant (K) for the reaction. A+2BhArr2C+D is:

The equilibrium constant for the reactions A+B hArr AB is 0.5 at 200K . The equilibrium constant for the reaction AB hArr A+B would be

For reaction 2A+B hArr 2C, K=x Equilibrium constant for C hArr A+1//2 B will be

For the hypothetical reactions, the equilibrium constant (K) value are given AhArrB,K_(1)=2,BhArrC,K_(2)=4, ChArrD,K_(3)=3 The equilibrium constant (K) for the reaction AhArrD is

For the hypothetical reactions, the equilibrium constant (K) value are given AhArrB,K_(1)=2,BhArrC,K_(2)=4, ChArrD,K_(3)=3 The equilibrium constant (K) for the reaction AhArrD is

For A+BhArrC+D , the equilibrium constant is K_(1) and for C+DhArrA+B , the equilibrium constant is K_(2) . The correct relation between K_(1) and K_(2) is

In a chemical reaction , A+2Boverset(K)hArr2c+D, the initial concentration of B was 1.5 times of the concentrations of A , but the equilibrium concentrations of A and B were found to be equal . The equilibrium constant (K) for the aforesaid chemical reaction is :

In a chemical reaction , A+2Boverset(K)hArr2c+D, the initial concentration of B was 1.5 times of the concentrations of A , but the equilibrium concentrations of A and B were found to be equal . The equilibrium constant (K) for the aforesaid chemical reaction is :

Given i) A harr B+C K_(eq)(1) ii) B+C harr P K_(eq)(2) then K_(eq) for reaction Aharrp is