At room temperature, the equilibrium constant for the reaction P + Q `hArr` R + S was calculated to be `4.32` . At `425^(@)C` the equilibrium constant became `1.24xx10^(-2)` . This indicates that the reaction

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

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

If the equilibrium constant for the reaction A_(2)+B_(2) hArr 2AB is K, then the backward reaction, AB hArr 1/2 A_(2)+1/2 B_(2) the equilibrium constant is 1//K .

The equilibrium constant, K for the reaction : 2HI (g) hArr H_(2)(g)+I_(2)(g) at room temperature is 2.85 and that of at 698 K is 1.4 xx 10^(-2) . This implies that the forward reaction is

If equilibrium constant for the reaction A_(2)+B_(2) hArr 2AB is k, then for the backward reaction AB hArr 1//2 A_(2)+1//2B_(2) the equilibrium constant k' is 1//K .

The equilibrium constant for a reaction A+2B hArr 2C is 40 . The equilibrium constant for reaction C hArr B+1//2 A is

An equilibrium constant of 10^(-4) for a reaction means, the equilibrium is

At a given temperature the equilibrium constant for the reaction PCl_(5) (g) Leftrightarrow PCl_(3)(g)+Cl_(2)(g) is 2.4 xx 10^(-3) . At the same temperature the equilibrium constant for the reaction PCl_(3) (g)+Cl_(2)(g) Leftrightarrow PCl_(5) (g)

The equilibrium constant for the reaction 2A+2B hArr 2C+2D is 200 . The equilibrium constant for the reaction A+B hArr C+D , at the same temperature is ………..