32 g of `O_(2)` is contained in a cubical container of side 1 m and maintained at a temperature of `127^(@)C`. The isothermal bulk modulus of elasticity of the gas is (universal gas constant = R)

A given quantity of a ideal gas is at pressure P and absolute temperature T. The isothermal bulk modulus of the gas is

A given quantity of a ideal gas is at pressure P and absolute temperature T. The isothermal bulk modulus of the gas is

Internal energy of two moles of an ideal gas at a temperature of 127^(@)C is 1200R . Then find the molar specific heat of the gas at constant pressure?

The bulk modulus of an ideal gas at constant temperature

A gas is filled in a container at 27^@ C . On increasing the temperature to 127^@ C , 1 litre (having (1)/(4) th mass) of the gas escape out of the container. Calculate the volume of the container.

A cubical vessel of side 15cm contains oxygen gas at 27^(@)C . How long does it take a typical molecule to cross the container?

A gas is filled in a container of volume V at constant pressure and at 27^(@)C temperature. Find out the amount of gas that will escape out of the container if temperature rises to 37^(@)C

A rigid container of negligible heat capacity contains one mole of an ideal gas. The temperatures of the gas increases by 1^@C if 3.0 cal of heat is added to it. The gas may be

A flask is filled with 13 g of an ideal gas at 27^(@)C and its temperature is raised to 52^(@)C . The mass of the gas that has to be released to maintain the temperature of the gas in the flask at 52^(@)C , the pressure remaining the same is

A flask is filled with 13 g of an ideal gas at 27^(@)C and its temperature is raised to 52^(@)C . The mass of the gas that has to be released to maintain the temperature of the gas in the flask at 52^(@)C , the pressure remaining the same is