Derive the relation `K_(p)=K_(c)(RT)^(Deltan_(g))` for a general chemical equilibrium reaction.

In which of the reaction K_p = K_c

Write the relation betweenn DeltaG^(0) and the equilibrium constant (K) for a reaction at TK. Using this relation state that for what value of DeltaG^(0) , the value of K will be K gt 1, K lt 1 , K=1 .

What is equilibrium constant? Establish the relation between K_p and K_c for a reversible reaction in equilibrium.

Derive thevrelationship between K_P and K_C .

Find out the equilibrium constant for the reaction, XeO_(4)(g)+2HF(g)hArr XeO_(3)F_(2)(g)+H_(2)O(g) consider K_(1) as the equilibrium constant for the reaction, XeF_(6)(g)+H_(2)O(g)hArr XeOF_(4)(g)+2HF(g) and K_(2) as the equilibrium constant for the reaction, XeO_(4)(g)+XeF_(6)(g) hArr XeOF_(4)(g)+XeO_(3)F_(2)(g) .

What will be the relation between K_(p) and K_(c) for the given equilibrium ? CO(g)+H_(2)O(g)hArrCO_(2)(g)+H_(2)(g) .

The total pressure at equilibrium of the reaction, XY(g)hArrX(g)+Y(g) is P . If the equilibrium constant for the reaction is K_p and K_p=P/8 , then the percent dissociation of XY is

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) .

Derive the expressions for K_(c) and K_(p) for decomposition of PCl_(5) .

In the reaction, H_(2)(g)+I_(2)(g)hArr 2HI(g) , the value of equilibrium constant (K_(P)) changes with change in _____.