For the reaction `N_2O_4 (g) overset(rightarrow)(leftarrow)2NO_2 (g)` at equilibrium the degree of dissociation `(alpha)` is 28% at temperature 318 K and total pressure 2 atm. Calculate the `K_P` and `K_C` for the reaction.

For the reaction 2NH_3 (g) overset(rarr) (larr) N_2 (g) + 3H_2 (g) the unit of the K_p will be

Establish the relation between K_p and K_C for the reaction. N_2(g) + 3H_2 (g) overset(rightarrow)(leftarrow) 2NH_3 (g) '. What will be the effect of the addition of insert gas on the equilibrium of the above gaseous reaction at constant pressure?.State Le-chatelicr’s principle.

Find out K_p//K_c for: CO(g)+frac 1/2 O_2 (g) overset (rarr)(larr) CO_2 (g) .

For the reaction N_2 (g) + O_2 (g) overset(rightarrow)(leftarrow) 2NO (g) the equilibrium constant is K_1 . The equilibrium constant is K_2 for the reaction , 2NO(g) + O_2 (g) overset(rightarrow)(leftarrow) 2NO_2 (g). What is K for the reaction, NO_2 (g) overset(rightarrow)(leftarrow) 1/2N_2(g)+ O_2 (g) -

At 318K and 2 atm total pressure the degree of dissociation (alpha) is 28% at the equilibrium condition for the reaction N_(2)O_(4)(g)hArr 2NO_(2)(g) . Calculate K_(p) & K_(c) .

For the reaction, 2HI(g) iff H_2(g) +I_2 (g) the degree of dissociation ( alpha ) of HI (g) is related to the equilibrium constant, K_p by expression

The following equilibrium is established during thermal dissociation of H_2O (g) in a closed vessel H_2O (g)overset(rightarrow)(leftarrow)H_2(g)+1//2 O_2(g) If the total pressure, equilibrium constant and degree of dissociation is 'P',‘K_P’ and x, then show that, K_P =(x^(3//2)P^(1//2))/((1-x)(2+x)^(1/2))

The equilibrium constant (K_P) for the decomposition of gaseous H_2O, H_2O(g)toH_2(g)+1/2O_2(g) , is related to degree of dissociation (prop) at a total pressure ( P) as-

K_c for the synthesis of HI(g) from H_2(g) and I_2(g) is 50 The degree of dissociation of HI is