For the equilibrium in a closed vessel`" "PCl_(5)(g) hArr PCl_(3)(g)+Cl_(2)(g)`,
`K_(p)` is found to be double of `K_(e)` . This is attained when `:`

For the equilibrium in a closed vessel " "PCl_(5)(g) hArr PCl_(3)(g)+Cl_(2)(g) , K_(p) is found to be half of K_(c) . This is attained when :

For the reaction : PCl_(5) (g) rarrPCl_(3) (g) +Cl_(2)(g) :

For the reaction : PCl_(5) (g) rarrPCl_(3) (g) +Cl_(2)(g) :

For the following equilibrium N_(2)O_(4)(g)hArr 2NO_(2)(g) K_(p) is found to be equal to K_(c) . This is attained when :

For the reaction PCl_(5)(g) rightarrow PCl_(3)(g) + Cl_(2)(g)

For PCl_(5)(g)hArrPCl_(3)(g)+Cl_(2)(g), write the expression of K_(c)

For the following gases equilibrium, N_(2)O_(4)(g)hArr2NO_(2)(g) K_(p) is found to be equal to K_(c) . This is attained when:

For the following gases equilibrium, N_(2)O_(4) (g)hArr2NO_(2) (g) , K_(p) is found to be equal to K_(c) . This is attained when:

Unit of equilibrium constant K_p for the reaction PCl_5(g) hArr PCl_3(g)+ Cl_2(g) is

For the following gaseous phase eqilibrium PCl_(5(s)) hArr PCl_(3(g))+Cl_(2(g)) Kp is found to be equal to K_(x) K_(x) is equilibrium constant when concentratiion are taken in interms of mole fraction). This attained when