At `273K` and `1` atm ,a moles of `N_(2)O_(4)` decomposes to `NO_(2)` according to equation `N_(2)O_(4)(g) hArr 2NO_(2)(g)`. To what extent has the decomposition proceeded when the original volume is `25%` less than that of exisiting volume?

At 273K and 1 atm a L of N_(2)O_(4) decomposes to NO_(2) according to equation N_(2)O_(4)(g) hArr 2NO_(2)(g) . To what extent ha the decomposition proceeded when the original volume is 25% less than that of exisiting volume?

At 273 K one atm, 'a' litre of N_(2)O_(4) decomposes to NO_(2) as : N_(2)O_(4)(g) hArr 2NO_(2)(g) . To what extent has the decomposition proceeded when he original volume is 25% less then that of existing volume ? [Report your answer up to decimal places.]

At 273 K and 1atm , 10 litre of N_(2)O_(4) decompose to NO_(4) decompoes to NO_(2) according to equation N_(2)O_(4)(g)hArr2NO_(@)(G) What is degree of dissociation (alpha) when the original volume is 25% less then that os existing volume?

If in the reaction, N_(2)O_(4)(g)hArr2NO_(2)(g), alpha is the degree of dissociation of N_(2)O_(4) , then the number of moles at equilibrium will be

At 60^(@) and 1 atm, N_(2)O_(4) is 50% dissociated into NO_(2) then K_(p) is

For the following equilibrium N_(2)O_(4)(g)hArr 2NO_(2)(g) K_(p) is found to be equal to K_(c) . This is attained when :

Gaseous N_(2)O_(4) dissociates into gaseous NO_(2) according to the reaction : [N_(2)O_(4)(g)hArr2NO_(2)(g)] At 300 K and 1 atm pressure, the degree of dissociation of N_(2)O_(4) is 0.2. If one mole of N_(2)O_(4) gas is contained in a vessel, then the density of the equilibrium mixture is :

For the following gases equilibrium, N_(2)O_(4)(g)hArr2NO_(2)(g) K_(p) is found to be equal to K_(P) . This is attained when: