A vessel contains `N_(2)O_(4)` & `NO_(2)` in 2:3 molar ratio at 10 atm under equilibrium. Now, `K_(P)` for `N_(2)O_(4) harr 2NO_(2)` is

Vapour density of the equilibrium mixture of NO_(2) and N_(2)O_(4) is found to be 40 for the equilibrium N_(2)O_(4) harr 2NO_(2) . From this information answer the following Percentage of NO_(2) in the mixture is

Vapour density of the equilibrium mixture of NO_(2) and N_(2)O_(4) is found to be 40 for the equilibrium N_(2)O_(4) harr 2NO_(2) . From this information answer the following Abnormal molecular weight is

Vapour density of the equilibrium mixture of NO_(2) and N_(2)O_(4) is found to be 40 for the equilibrium N_(2)O_(4) harr 2NO_(2) . From this information answer the following Degree of dissociation of N_(2)O_(4) is

If the % dissociation of N_(2) O_(4) is 50 , the ratio of Kp and P_(eq) for N_(2) O_(4) hArr 2 NO_(2) becomes equal to

The equilibrium constant Kp for the reaction N_(2)O_(4(g)) hArr 2NO_(2(g)) is 4.5. What would be the average molar naSs (in g/mol) of an eyuilibriunm mixture of N_(2)O_(4) and NO_(2) formed by the dissociation of pure V_(2) O_(4) at a total pressure of 2 atm ?

The equilibrium constant of the reaction, SO_(2)(g) + 1/2 O_(2)(g) hArr 2SO_(3)(g) is 5 xx 10^(-2)atm . The equilibrium constant of the reaction, 2SO_(3)(g) hArr 2SO_(2)(g) + O_(2)(g)

For the gaseous reactions (I) and (II) the equilibrium constants are X and Y respectively. I. (1)/(2)N_(2)(g) + O_(2) (g) hArr NO_(2)(g) (II) 2NO_(2)(g) hArr N_(2)O_(4) (g) Using the above reactions the equilibrium constant Z for the reaction (III) given below is III. N_(2)O_(4)(g) hArr N_(2)(g) + 2O_(2) (g)