`0.5 mol` of `H_(2)`, `SO_(2)`, and `CH_(4)` is kept in a container. A hole was made in the container. After `3 hours`, the order of partial pressure in the container will be

Equal moles of each of SO_(3), CO_(2)O_(2) and H_(2) are kept in a container. A hole is made in the container and gasses are allowed to effuse. After 5 minutes the order of partial pressure of each gas in the container would be :

Equal moles of each H_2 , CH_4 and SO_3 are kept in a vessel. A hole is made in vessel. After an hour the partial pressures of gases will be in the order of

Equal moles of each H_2 , CH_4 , and SO_3 , are kept in a vessel A hole is made in vessel. After an hour the partial pressures of gases will be in the order of

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 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

Equal mass of H_(2) , He and CH_(4) are mixed in empty container at 300 K, when total pressure is 2.6 atm The partial pressure of H_(2) in the mixture is

Equal molecules of N_2 and O_2 are kept in a closed container at pressure P. If N_2 is removed from the system, then the pressure of the container will be

Same mass of CH_(4) and H_(2) is taken in container. The partial pressure caused by H_(2) is

Equal molecules of N_(2) and O_(2) are kept in closed container at pressure P . If N_(2) is removed from the system, then what will be the pressure of the container?