For the reaction `A+B hArr C`, the rate constants for the forward and the reverse reactions are `4xx10^(2)` and `2xx10^(2)` respectively. The value of equilibrium constant K for the reaction would be

For the reaction, A(g)+2B(g) hArr 2C(g) , the rate constant for forward and the reverse reactions are 1xx10^(-4) and 2.5xx10^(-2) respectively. The value of equilibrium constant, K for the reaction would be

For the reversible reaction, A+BhArrC , the specific reaction rates for forward and reverse reactions are 1.25xx10^(3) "and" 2.75xx10^(4) respectively. The equilibrium constant for the reaction is:

For an equilibrium reaction, the rate constants for the forward and the backward reaction are 2.38xx10^(-4) and 8.15xx10^(-5) , respectively. Calculate the equilibrium constant for the reaction.

The unit of equilibrium constant K_(c) for the reaction A+B hArr C would be

The rate constant for forward and backward reactions of hydrolysis of ester are 1.1xx10^(-2) and 1.5xx10^(-3) per minute respectively. Equilibrium constant for the reaction is

The rate constant for forward and backward reactions of hydrolysis of ester are 1.1xx10^(-2) and 1.5xx10^(-3) per minute respectively. Equilibrium constant for the reaction is

For the reaction, A+2B hArr C , the expession for equilibrium constant is

The equilibrium constant for the reaction A(g)hArrB(g) and B(g)hArrC(g) are K_1=10^(-2) and K_2=10^(-1) respectively . Equilibrium constant for the reaction (1/2)C(g)hArr(1/2)A(g) is

The rate constant for a forward reaction in a reversible reaction (K_(eq) = 10^(6)) is 10^(2) . Calculate rate constant for its backward reaction

In a reaction A+BhArrC+D the rate constant of forward reaction & backward reaction is K_(1) and K_(2) then the equilibrium constant (K) for reaction is expressed as: