For the equilibrium `2NOBr(g) hArr 2NO(g) +Br_2(g)`
if `P_(Br_2) =P/9` equilibrium and P is total pressure, the ratio of `(K_p)/(P)` is equal to

For the reaction is equilibrium : 2NOBr_((g))hArr2NO_((g))+Br_(2(g)) If P_(Br_(2)) is (P)/(9) at equilibrium and P is total pressure, prove that (K_(p))/(P) is equal to (1)/(81) .

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.

For the equilibrium 2NOCl(g) hArr 2NO(g)+Cl_(2)(g) the value of the equilibrium constant, K_(c) is 3.75 xx 10^(-6) at 1069 K . Calcualate the K_(p) for the reaction at this temperature?

For the following equilibrium : Si(s)+2Cl_(2)(g) hArr SiCl_(4)(g) , if P is total pressure then degree of dissociation (x) is related to P as (Presume x to very small)

On decomposition of NH_(4)HS , the following equilibrium is estabilished: NH_(4) HS(s)hArrNH_(3)(g) + H_(2)S(g) If the total pressure is P atm, then the equilibrium constant K_(p) is equal to

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 NH_(4)HS(s)hArr NH_(3)(g)+H_(2)S(g) If K_(p)=64atm^(2) , equilibrium pressure of mixture is

For the following equilibrium, 2SO_(2)(g) +O_(2)(g) hArr 2SO_(3)(g) the total equilibrium pressure is P_(1) . If volume of the system is reduced to 1//2 of this initial volume then equilibrium is restablished. The new equilibrium total pressure will be :

2NOBr(g)hArr2NO(g)+Br2(g). If nitrosyl bromide (NOBr) 40% dissociated at certain temp. and a total pressure of 0.30 atm K_(p) for the reaction 2NO(g)+Br_(2)(g)hArr2NOBr(g) is

For A(g) hArr 2B(g) , equilibrium constant at total equilibrium pressure p_(1) is K_(p1)& for C(g)hArrD(g)+E(g) . equilibrium constant at total equilibrium pressure p_(2) is K_(p2) . If degree of dissciation of A & C are same, then the ratio K_(p1) //K_(p2) , if 2p_(1)=p_(2) , is :