For the equilibrium `N_(2)O_(4(g))hArr 2NO_(2(g))`, the `K_(p) and K_(c )` values are related as

For the equilibrium 2NOCl_((g))hArr2NO_((g))+Cl_(2(g)) the value of the equilibrium constant K_(c) is 3.75xx10^(-6) at 790^(@)C . Calculate K_(p) for this equilibrium at the same temperature.

At 318K and 2 atm total pressure the degree of dissociation (alpha) is 28% at the equilibrium condition for the reaction N_(2)O_(4)(g)hArr 2NO_(2)(g) . Calculate K_(p) & K_(c) .

4NH_(3)(g)+5O_(2)(g)hArr 4NO(g)+6H_(2)O(g) . Write the K_(p) and K_(c) values for the above reaction and also make a relation between them.

At 450K, K_(p)=2.0xx10^(10) /bar for the given reaction at equilibrium, 2SO_(2)(g)+O_(2)hArr 2SO_(3)(g) . What is K_(c) at this temperature.

At 35^(@)C , the value of K_(p) for the equilibrium reaction N_(2)O_(4)hArr2NO_(2) is 0.3174 , Calculate the degree of dissociation when P is 0.2382 atm

At 298K, for attainment of equilibrium of the reaction N_(2)O_(4)(g)hArr 2NO_(2)(g) , 5 mol of each of the constituents is taken. Due to this, total pressure of the mixture turns 20 atm. If DeltaG_(f)^(0)(N_(2)O_(4))=100kJ*mol^(-1) and DeltaG_(f)^(0)(NO_(2))=50K(J*mol^(-1)) then- (1) Give the value of DeltaG of the reaction? (2) In which direction will the reaction proceed more to attain equilibrium?

For the reaction 2H_(2)(g)+O_(2)(g)hArr 2H_(2)O(g)-K_(p)=K_(c)(RT)^(x) . Find the value of x.

A sample of air consisting mainly of N_2 and O_2 is heated at 2500K till the given equilibrium attains- N_2(g) + O_2 (g) hArr 2NO(g) . If the value of equilibrium constant (K_c) at this temperature is 2.1xx10^(-3) and the percentage of number of moles of NO(g) in the above equilibrium mixture is 1.8 %, then what will be the mole fractions of N_2 and O_2 in the sample of air used'?

Calculate the value of K_c for the given reactions: N_2O_4(g)hArr 2NO_2(g),K_p=11 ( at 100^(@)C )