4 mole of `N_(2)O_(4)` is taken in container of unit volume at any temperature. After some time, equlibrium is attained and vapour density of mixture is `34.5.` The value of `Delta G` will be

A gas is found to have the formula (C_(3)O_(2)) . Its vapour density is 34. The value of n will be…..

Vapour density of a gas is 11.2. Volume occupied by 2.4 g of this at STP will be

The equilibrium SO_(2)(g)+(1)/(2)O_(2)(g)hArrSO_(3)(g) is established in a container of 4L at a particular temperature. If the number of moles of SO_(2),O_(2) "and" SO_(3) at equilibrium are 2,1 "and" 4 respectively then find the value of equilibrium constant.

For the equation N_(2)O_(5)(g)=2NO_(2)(g)+(1//2)O_(2)(g) , calculate the mole fraction of N_(2)O_(5)(g) decomposed at a constant volume and temperature, if the initial pressure is 600 mm Hg and the pressure at any time is 960 mm Hg . Assume ideal gas behaviour.

For the equation N_(2)O_(5)(g)=2NO_(2)(g)+(1//2)O_(2)(g) , calculate the mole fraction of N_(2)O_(5)(g) decomposed at a constant volume and temperature, if the initial pressure is 600 mm Hg and the pressure at any time is 960 mm Hg . Assume ideal gas behaviour.

Equal moles of N_2 , H_2 and NH_3 are present in a container which are effusing from an orifice at temperature 27°C. After passing some time the correct order of their partial pressure in the container is

A mixture contains N_(2)O_(4) and NO_(2) in the ratio 2:1 by volume. Calculate the vapour density of the mixture?

A mixture of one mole of each of O_2(g), H_2(g) , He(g) exists in a container of volume V at temperatureT in which partial pressure of H_2 (g) is 2atm. the total pressure in the container is:

A mixture of one mole of each of O_2(g), H_2(g) , He(g) exists in a container of volume V at temperatureT in which partial pressure of H_2 (g) is 2atm. the total pressure in the container is:

Equal masses of H_2, O_2 , and methane have been taken in a container of volume V at temperature 27^@C in identical conditions. The ratio of the volumes of gases H_2 : O_2 : CH_4 would be