The equilibrium constant for the reaction, `A+B hArr C+D` is `2.85` at room temperature and `1.4xx10^(-2)` at `698 K`. This shows that the forward reaction is

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

The equilibrium constants for the reaction, A_2hArr2A A at 500K and 700K are 1xx10^(-10) and 1xx10^(-5) . The given reaction is

The equilibrium constant K for the reaction 2HI(g) hArr H_(2)(g)+I_(2)(g) at room temperature is 2.85 and that at 698 K is 1.4 xx10^(-2) . This implies

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

The equilibrium constant for a reaction A+B hArr C+D is 1xx10^(-2) at 298 K and is 2 at 273 K. The chemical process resulting in the formation of C and D is :

The equilibrium constant for a reaction A+B hArr C+D is 1xx10^(-2) at 298 K and is 2 at 273 K . The chemical process resulting in the formation of C and D is

The equilibrium constant for the reaction N_2(g)+O_2(g) hArr 2NO(g) at temperature T is 4xx10^(-4) .The value of K_C for the reaction, NO(g) hArr 1/2 N_2(g)+1/2O_2(g) at the same temperature is :

The equilibrium constant for the reaction N_(2)(g)+O_(2)(g) hArr 2NO(g) at temperature T is 4xx10^(-4) . The value of K_(c) for the reaction NO(g) hArr 1/2 N_(2)(g)+1/2 O_(2)(g) at the same temperature is

The equilibrium constant for a reaction A+B hArr C+D is 1.0xx10^(-2) at 298 and is 2.0 at 373 K . The chemical process resulting in the foemation of C and D is