For the decomposition reaction
`NH_2COONH_4 (s) hArr 2NH_3(g) +CO_2(g)`
The `K_p=2.9 xx 10^(-5) atm^3`. The total pressure of gases at equilibrium when 1 mole of `NH_2COONH_4` (s) was taken to start with would be

For the decomposition reaction NH_(2)COONH_(4)(s) hArr2NH_(3)(g)+CO_(2)(g) , the K_(p)=3.2xx10^(-5)atm^(3) . The total pressure of gases at equilibrium when 1.0 mol of NH_(2)COONH_(4)(s) was taken to start with will be:

For the reaction NH_(2)COONH_(4)(g)hArr 2NH_(3)(g)+CO_(2)(g) the equilibrium constant K_(p)=2.92xx10^(-5)atm^(3) . The total pressure of the gaseous products when 1 mole of reactant is heated, will be

Solid ammonium carbamate dissociated according to the given reaction NH_2COONH_4(s) hArr 2NH_3(g) +CO(g) Total pressure of the gases in equilibrium is 5 atm. Hence K_p .

For the equilibrium reaction NH_4Cl hArr NH_3(g)+HCl(g), K_P=81 "atm"^2 .The total pressure at equilibrium is 'X' times the pressure of NH_3 .The value of X will be

The value of K_(P) for NH_(2)COONH_(4(s))hArr 2NH_(3(g))+CO_(2(g)) if the total pressure at equilibrium is P :-

Ammonium carbamate decomposes as : NH_(2)COONH_(4) (s) rarr 2NH_(3)(g) + CO_(2)(g) For the reaction, K_(P) = 2.9 xx 10^(-5) atm^(3) If we start with 1 mole of the compound, the total pressure at equilibrium would be

For the reactions, N_2(g) + 3H_2(g) hArr 2NH_3(g), " " K_p=K_c (RT)^(…..)

Ammonium carbamate decomposes as : NH_(2)COONH_(4) rarr 2NH_(3)(g) + CO_(2)(g) For the reaction, K_(P) = 2.9 xx 10^(-5) atm^(3) If we start with 1 mole of the compound, the total pressure at equilibrium would be

For the reaction C(s) +CO_(2)(g) rarr 2CO(g) , k_(p)=63 atm at 100 K. If at equilibrium p_(CO)=10p_(CO_(2)) then the total pressure of the gases at equilibrium is

For the reaction C(s) +CO_(2)(g) rarr 2CO(g), k_(p)=63 atm at 100 K. If at equilibrium p_(CO)=10p_(CO_(2)) then the total pressure of the gases at equilibrium is