`N_(2)O_(4)(g)` is dissociated to an extent of `20%` at equilibrium pressure of `1.0` atm and `57^(@)C`. Find the percentage of `N_(2)O_(4)` at `0.2` atm and `57^(@)C`.

N_(2)_(4) is 25% dissociated at 37^(@)C and one atmosphere pressure. Calculate (i) K_(p) and (ii) the percentage dissociation at 0.1 atm and 37^(@)C

N_(2)O_(4) is dissociated to 33% and 50% at total pressure P_(1) and P_(2)atm respectively. The ratio of P_(1)//P_(2) is:

For the reaction, N_(2)O_(4)(g)hArr 2NO_(2)(g) the degree of dissociation at equilibrium is 0.14 at a pressure of 1 atm. The value of K_(p) is

N_(2)O_(4) is 60% dissociated into NO_(2) at 340K and 1 atm pressure. Find the volume of 10 g N_(2)O_(4) occupy under these condition.

N_(2)O_(3) dissociates into NO and NO_(2) . At equilibrium pressure of 3 atm , all three gases were found to have equal number of moles in a vessel. In another vessel, equimolormixture of N_(2)O_(3), NO and NO_(2) are taken at the same temperature but at an initial pressure of 9 atm then find the partial pressure of NO_(2) (in atm ) at equilibrium in second vessel! N_(2)O_(3)(g) hArr NO(g) + NO_(2) (g)

For the reaction , N_2O_4(g)hArr2NO_2(g) the degree of dissociation at equilibrium is 0.4 at a pressure of 1 atm. The value of K_p is

At 27^(@)C and 1 atm pressure , N_(2)O_(4) is 20% dissociation into NO_(@) .What is the density of equilibrium mixture of N_(2)O_(4) and NO_(2) at 27^(@)C and 1 atm?

If "66%" of "N_(2)O_(4)(g)" is dissociated into "NO_(2)(g)" at "27^(@)C" and "1" atm pressure,the volume occupied by 11.5g" of "N_(2)O_(4)" would be about

N_(2)O_(4) is 25% dissociated at 37^(@)C and 1 atm . Calculate (i) K_(p) and (ii) the percentage dissociation at 0.1 atm and 37^(@)C .