`NH_(4)HS(s)hArrNH_(3)(g)+H_(2)S(g)`
The equilibrium pressure at `25^(@)C` is 0.660 atm . What is `K_(p)` for the reaction ?

For MgO_((g)) + C_((g)) hArr Mg_((g)) + CO_((g)) , equilibrium pressure at 2000 K is 100 atm . Now K_(p) for the process is (in atm^(2))

For the following reaction NH_(4)HS_((s)) harr NH_(3(g))+H_(2)S_((g)) the total pressure at equilibrium is 30 atm. The value of K_(P) is

H_(2)S_((g)) intially at a pressure of 10 atm anda temperature of 800K, dissociates as 2H_(2)S_((g)) hArr 2H_(2) +S_(2(g)) At equilibrium, the partial pressure of S, vapour is 0.02 atm. Thus, K_(p) is

In the reaction C_((s)) + CO_(2(g)) hArr CO_(2(g)) , the equilibrium pressure is 6.75 atm. If 50% of CO_(2) reacts then the find value of K_(p) .

A sample of HI(g) is placed in flask at a pressure of 0.2 atm. At equilibrium the partial pressure of HI(g) is 0.04 atm. What is K_(p) for the given equilibrium ? 2HI(g)hArrH_(2)(g)+I_(2)(g)

For the equilibrium , 2NOCl(g)hArr2NO(g)+Cl_(2)(g) the value of the equilibrium constant, K_(c) is 3.75xx10^(-6) at 1069K . Calculate the K_(p) for the reaction at this temperature ?

For the reaction, 0.5 C(s)+0.5CO_(2)(g) hArr CO(g) the equilibrium pressure is 12 atm. If CO_(2) conversion is 50%, the value of K_(p) , in atom is

As per law of mass action, for NH_(4) HS(s) hArr NH_(3)(g) + H_(2) S(g) ratio of rate constants of forward (K_(f)) & backword (K_(b)) reactions at equilibrium equals ot

At 100 K the partial pressure of CO_(2) (g ) and CO (g) for the reaction CO_(2)(g) + C(s) hArr 2CO (g ) in a closed vessel at equilibrium are 0.15 and 0.60 bar respectively . The K_(c ) for this reaction at the same temperature is approximately