For the reaction, `AB(g)hArr A(g)+B(g), AB" is "33%` dissociated at a total pressure of 'p' Therefore, 'p' is related to `K_(p)` by one of the following options

For the reaction, N_(2)O_(4)(g)hArr 2NO_(2)(g) the degree of dissociation at equilibrium is 0.l4 at a pressure of 1 atm. The value of K_(p) is

For the reaction 2HI(g)hArrH_(2)(g)+I_(2)(g) The degree of dissociation (alpha) of HI(g) is related to equilibrium constant K_(p) by the expression a. (1+2sqrt(K_(p)))/2 , b. sqrt((1+2K_(p))/2) c. sqrt((2K_(p))/(1+2K_(p))) , d. (2sqrt(K_(p)))/(1+2sqrt(K_(p)))

K_p for the equation A(s)⇋ B(g) + C(g) + D(s) is 9 atm^2 . Then the total pressure at equilibrium will be

For the reaction, A_((g))+2B_((g))hArr 3C_((g))+3_((g)),K_(p)=0.05" atm at "1000K . The value of K_(c) is represented by

At temperature T, a compound AB_(2)(g) dissociates according to the reaction 2AB_(2)(g)hArr2AB(g)+B_(2)(g) with degree of dissociation alpha , which is small compared with unity. The expression for K_(p) in terms of alpha and the total pressure P_(T) is

At certain temperature compound AB_(2)(g) dissociates according to the reaction 2AB_(2)(g) hArr2AB (g)+B_(2)(g) With degree of dissociation alpha Which is small compared with unity, the expression of K_(p) in terms of alpha and initial pressure P is :

For the equilibrium AB(g) hArr A(g)+B(g) . K_(p) is equal to four times the total pressure. Calculate the number moles of A formed if one mol of AB is taken initially.

At 600^(@)C,K_(P) for the following reaction is 1 atm. X(g) rarr Y(g) + Z(g) At equilibrium, 50% of X (g) is dissociated. The total pressure of the equilibrium system is p atm. What is the partial pressure (in atm) of gases at equilibrium ?

In the reversible reaction, 2HI(g) hArr H_(2)(g)+I_(2)(g), K_(p) is

For the reaction, N_(2)(g)+3H_(2)(g) hArr 2NH_(3)(g) , the units of K_(p) are …………