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)`.

K_(p) has the value of 10^(-6) atm^(3) and 10^(-4)atm^(3) at 298 K and 323 K respectiely for the reaction CuSO_(4).3H_(2)O(s)hArrCuSO_(4)(s)+3H_(2)O(g) Delta_(r)H^(@) for the reaction is :

For the equilibrium H_(2) O (1) hArr H_(2) O (g) at 1 atm 298 K

The value of K_(p) for the following reaction 2H_(2)S(g)hArr2H_(2)(g) + S_(2)(g) is 1.2xx10^(-2) at 10.6.5^(@)C . The value of K_(c) for this reaction is

The value of K_(c) = 4.24 at 800 K for the reaction. CO(g) + H_(2)O(g) hArr CO_(2)(g)+H_(2)(g) Calculate equilibrium concentration of CO_(2), H_(2), CO and H_(2)O at 800K . If only CO and H_(2)O are present initially at concentrations of 0.10 M each.

For the reaction: 4NH_(3)(g)+7O_(2(g))hArr4NO_(2(g))+6H_(2)O_(g).K_(p) is related to K_(c) by

Calculate the precentage dissociation of H_(2)S(g) if 0.1 mol of H_(2)S is kept in a 0.5 L vessel at 1000 K . The value of K_(c ) for the reaction 2H_(2)ShArr2H_(2)(g)+S_(2)(g) is 1.0xx10^(-7).

What is % dissociation of H_(2)S if 1 "mole" of H_(2)S is introduced into a 1.10 L vessel at 1000 K ? K_(c) for the reaction 2H_(2)S(g) hArr 2H_(2)(g)+S_(2)(g) is 1xx10^(-6)

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 the equilibrium constant for the reaction, H_(2(g))+CO_(2(g))hArrH_(2)O_((g))+CO_((g)) at 1395 K , if the equilibrium constants at 1395 K for the following are: 2H_(2)O_((g))hArr2H_(2)+O_(2(g)) ( K_(1)=2.1xx10^(-13) ) 2CO_(2(g))hArr2CO_((g))+O_(2(g)) ( K_(2)=1.4xx10^(-12) )

Calorific value of ethane, in k J/g if for the reaction 2C_(2)H_(6) + 7O_(2) rightarrow 4CO_(2) + 6 H_(2)O, Delta H = -745.6 kcal