For the reaction equilibrium , `N_2O_4(g) hArr 2NO_(2)(g)` the concentrations of `N_2O_4` and`NO_2` at equilibrium are `4.8xx10^(-2)` and `1.2xx10^(-2) mol L^(-1)` respectively.The value of `K_C` for the reaction is :

For the reaction equilibrium, N_(2)O_(4(g))hArr2NO_(2(g)) , the concentration of N_(2)O_(4) and NO_(2) at equilibrium are 4.8xx10^(-2) and 1.2xx10^(-2) mol/L respectively. The value of K_(c) for the reaction is:

For an equilibrium reaction, N_(2)O_(4)(g) hArr 2NO_(2)(g) , the concentrations of N_(2)O_(4) and NO_(2) at equilibrium are 4.8 xx 10^(-2) and 1.2 xx 10^(-2) mol//L respectively. The value of K_(c) for the reaction is

For the reaction, N_(2)O_(4)(g) hArr 2NO_(2)(g) , the concentration of an equilibrium mixture at 298 K is N_(2)O_(4)=4.50xx10^(-2) mol L^(-1) and NO_(2)=1.61xx10^(-2) mol L^(-1) . What is the value of equilibrium constant?

For the equilibrium reaction 2NO_2(g) hArr N_2O_4(g) + 60.0 kJ the increase in temperature

At 800 K in a sealed vessel for the equilibrium N_(2)(g) + O_(2) (g) hArr 2NO(g), the equilibrium concentrations of N_(2) (g), O_(2)(g) and NO(g) are respectively 0.36xx10^(-3) M, 4.41 xx 10^(-3) M and 1.4 xx 10^(-3) M. Calculate the value of K_(c) for the reaction NO(g) hArr 1//2 N_(2)(g) +1//2 O_(2) (g) at 800 K is :

For the reaction , A+2B hArr 2C , the rate constant for the forward and the backward reactions are 1xx10^(-4) and 2.5xx10^(-2) respectively.The value of equilibrium constant, K, for the reaction would be :

For the reaction , N_2O_4(g)underset(K_2)overset(K_1)hArr2NO_2(g) , the rate of disappearance of NO_2 will be