For the reaction (1)and(2)
`A(g)hArrB(g)+C(g)`
` X(g) hArr2Y(g)`
Given , `K_(p1):K_(p2)=9:1`
If the degree of dissociation of A(g) and X(g) be same then the total pressure at equilibrium
(1) and (2) are in the ratio:

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 CO(g)+(1)/(2) O_(2)(g) hArr CO_(2)(g),K_(p)//K_(c) is

For the reaction, CO(g) +(1)/(2) O_2(g) hArr CO_2 (g), K_p//K_c is equal to

In the reaction AB(g) hArr A(g) + B(g) at 30^(@)C, k_(p) for the dissociation equilibrium is 2.56xx10^(-2) atm . If the total pressure at equilibrium is 1 atm, then the percentage dissociation of AB is

For the reaction CO_((g)) + (1)/(2) O_(2(g)) to CO_(2(g)) K_(p)//K_(c) is

Show that K_p for the reaction, 2H_2S(g) hArr 2H_2(g) +S_2(g) is given by the expression K_p=(alpha^3P)/((2+alpha)(1-alpha)^2) where alpha is the degree of dissociation and P is the total equilibrium pressure. Calculate K_c of the reaction if alpha at 298 k and 1 atm . pressure is 0.055.

For the reaction N_(2)O_(4)(g)hArr2NO_(2)(g) , the degree of dissociation at equilibrium is 0.2 at 1 atm pressure. The equilibrium constant K_(p) will be

The degree of dissociation of SO_(3) is alpha at equilibrium pressure P_(0) . K_(P) for 2SO_(3)(g)hArr2SO_(2)(g)+O_(2)(g) is

For the reaction PCl_(5)(g)hArr PCl_(3)(g)+Cl_(2)(g) , the equation connecting the degree of dissociation (alpha) of PCl_(5)(g) with the equilibrium constant K_(p) is

For the reaction NH_(3)(g)hArr(1)/(2)N_(2)(g)+(3)/(2)H_(2)(g) Show that the degree of dissociation of NH_(3) is given as alpha=[1+(3sqrt(3))/4p/K_(p)]^(-1//2) where p is equilibrium pressure. If K_(p) of the above reaction is 78.1 atm at 400^(@)C , calculate K_(c ) .