`K_(a)` for the acid HA is `1xx10^(-6)`. The value of K for the reaction `A^(-)+H_(3)O^(+)hArr HA+H_(2)O ` is:-

Equilibrium constants for the following reaction 1200 K are given: 2H_2O (g) hArr 2H_2(g) +O_2(g) , " " K_1=6.4xx10^(-8) 2CO_2(g) hArr 2CO(g) +O_2(g) , " " K_2=1.6xx10^(-6) The equilibrium constant for the reaction H_2(g) + CO_2(g) hArr CO(g) +H_2O(g) at 1200 K will be

The equilibrium constant for the following reactions at 1400 K are given. 2H_(2)O(g)hArr2H_(2)(g) + O_(2)(g) , K_(1)=2.1×x10^(-13) 2CO_(2)(g) hArr2CO(g)+O_(2)(g),K_(2) = 1.4 x× 10^(-12) Then, the equilibrium constant K for the reaction H_(2)(g) + CO_(2)(g)hArrCO(g) + H_(2)O(g) is

The relation between K_(p) and K_(c) is K_(p)=K_(c)(RT)^(Deltan) unit of K_(p)=(atm)^(Deltan) , unit of K_(c)=(mol L^(-1))^(Deltan) The equilibrium constant of the following reactions at 400 K are given: 2H_(2)O(g) hArr 2H_(2)(g)+O_(2)(g), K_(1)=3.0xx10^(-13) 2CO_(2)(g) hArr 2CO(g)+O_(2)(g), K_(2)=2xx10^(-12) Then, the equilibrium constant K for the reaction H_(2)(g)+CO_(2)(g) hArr CO(g)+H_(2)O(g) is

The following equilibria are given by : N_(2)+3H_(2) hArr 2NH_(3), K_(1) N_(2)+O_(2) hArr 2NO,K_(2) H_(2)+(1)/(2)O_(2) hArr H_(2)O, K_(3) The equilibrium constant of the reaction 2NH_(3)+(5)/(2)O_(2)hArr 2NO +3H_(2)O in terms of K_(1) , K_(2) and K_(3) is

Calculate K for the reaction, A^(-)+H_(3)^(+)O hArr HA+H_(2)O if K_(a) value for the acid HA is 1.0xx10^(-6) .