Taking the volume of hydrogen `5000/7 cm^3`. What change must be made in Kelvin (absolute) temperature to return the volume to 2500 cm (pressure remaining constant).

Water decomposes to O_(2) and H_(2) under suitable conditions as represented by the equation below : H_(2)Oto2H_(2)+O_(2) taking the value of H_(2) what changes must be made in kelvin (absolute) temperature to return the volume to 2500 cm^(3) pressure remaining constant. (Use:5000/7cc=V2)

(a) 2500 "cm"^3 of hydrogen is taken at STP. The pressure of this gas is further increased by two and a half times (temperature remaining constant). What volume will hydrogen occupy now? (b)Taking the volume of hydrogen as calculated in the question (a), what change must be made in Kelvin (absolute) temperature to return the volume to 2500 "cm"^3 (pressure remaining constant)?

A gas at 240 K is heated to 127^@C . Find the percentage change in the volume of the gas (pressure remaining constant)

A gas occupies 3 litres at 0^@C What volume will it occupy at - 20^@C , pressure remaining constant

It is desired to reduce the volume of 1000 cm of a gas by 25% . To what temperature the gas be cooled if the initial temperature is 125^@C and the pressure remains constant ?

A sample of helium has a volume of 500 cm^3 at 373 K. Calculate the temperature at which the volume will become 260 cm^3 . Assume that the pressure is constant.

At what centigrade temperature will the volume of a gas at 0^(@)C triple itself if the pressure remains constant.

At what centigrade temperature will the volume of a gas at 0^@C triple itself if the pressure remains constant ?

The volume of a given mass of a gas at 15^@C is 100 cm^3 To what temperature should it be To what temperature should it be volume of 125 cm^3

A sample of helium gas has a volume of 500 cm^(3) at 373 K . Calculate the temperature at which the volume become 260 cm^(3) . Assume that pressure is kept constant.