For the equilibrium of the reaction `NH_(4) Cl(s) hArr NH_(3)` (g) + HCl (g) Kp = `81 atm^(2)`. Total pressure at equilibrium will be x times the pressure of `NH_(3)`. The value of x will be ........

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

K_p for the reaction NH_4HS (s) leftrightarrow NH_3(g) +H_2S (g) at certain temperature is 9 bar^2 Calculate the equilibrium pressure.

In the equilibrium NH_(4) HS_(s) hArr NH_(3(g)) + H_(2) S_((g)) . the forward reaction can be favoured by

Unit of K_p for NH_4COONH_(2(s)) harr 2NH_(3(g))+ CO_(2(g)) is

For the equilibrium at 2.0 bar N_(2(g)) + 3H_(2(g)) harr 2NH_(3(g)) [(del)/(del p) log K_(x)] = ?

A mixture of 1.57 mol of N_(2) , 1.92 mol of H_(2) and 8.13 mol of NH_(3) is introduced into a 20L reaction vessel at 500K . At this temperature, the equilibrium constant, K_(c) for the reaction N_(2)(g)+3H_(2)(g)hArr2NH_(3)(g) is 1.7xx10^(2) . Is the reaction mixture at equilibrium ? If not, what is the direction of the net reaction ?

The equilibrium pressure of NH_4CN_((s)) harr NH_(3(g))+HCN_((g)) is 4 atm. In an experiment, if NH_4CN_((s)) is allowed to decompose in presence of NH_3 at 3 atm, then

For the reaction equilibrium 2NOBr_((g)) hArr 2NO2_((g)) + Bz_(2(g)) . If PBr_(2) = (p)/(9) at equilibrium and P is total pressure, the ratio (K_(p))/(p) is equal to