`13.8g` of `N_(2)O_(4)` was placed in a `1L` reaction vessel at `400K` and allowed to attain equilibrium
`N_(2)O_(4)(g)hArr2NO_(2)(g)`
The total pressure at equilibrium was found to be `9.15` bar . Calcualate `K_(c)`, `K_(p)` and partial pressure at equilibrium.

18.4 g N_(2)O_(4) was placed in 1 L vessel at 400 K and allowed to attain the following equilibrium N_(2)O_(4)(g) hArr 2NO_(2)(g) . IF the total pressure at equilibrium was 10.64 bar, approximate K_(p) is (R = 0.083 L bar K^(-1) mol^(-1) ) (Assume N_(2)O_(4), NO_(2) as ideal gases)

For the following equilibrium, H_(2) O(l) hArr H_(2) O(g) the increase in the pressure causes

Derive the relation between K_(p) and K_(c) for the equilibrium reaction. N_(2)(g)+3H_(2)(g)hArr 2NH_(3)(g)

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

At 400K, in a 1.0L vessel N_2O is allowed to attain equilibrium N_(2)O_(4(g))hArr 2NO_(2(g)) . At equilibrium the total pressure is 600 mm Hg, when 20% of N_2O_4 is disscociated. The K_rho value for the reaction is

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 ?