Find the loss in the mass of 1 mole of an ideal monatomic gas kept in a rigid container as it cools down by `10^@C`. The gas constant `R = 8.3 J K ^(-1) mol ^(-1)`.

The total energy of 1 mol of an ideal monatomic gas at 27^(@)C is……. .

The kinetic energy of two moles of N_(2) at 27^(@) C is (R = 8.314 J K^(-1) mol^(-1))

Five moles of an ideal monoatomic gas with an initial temperature of 150^@C expand and in the process absorb 1500 J of heat and does 2500 J of work. The final temperature of the gas in .^@C is (ideal gas constant R = 8.314 J K^(-1)mol^(-1))

Half mole of an ideal monoatomic gas is heated at constant pressure of 1 atm from 20^(@)C " to " 90^(@)C . Work done by gas is close to: (Gas constant R = 8.31 J/mol-K)

The internal pressure loss of 1 mol of van der Waals gas over an ideal gas is equal to

Calculate the ratio (C_p / C_v) of oxygen from the following data . Speed of sound in oxygen (= 32g mol^(-1)) and the gas constant (R = 8.3 J K ^(-1) mol^(-1)) .

An ideal monatomic gas undergoes process PV^(1.25) = constant .Then

A closed container of volume 0.02m^3 contains a mixture of neon and argon gases, at a temperature of 27^@C and pressure of 1xx10^5Nm^-2 . The total mass of the mixture is 28g. If the molar masses of neon and argon are 20 and 40gmol^-1 respectively, find the masses of the individual gasses in the container assuming them to be ideal (Universal gas constant R=8.314J//mol-K ).

A closed container of volume 0.02m^3 contains a mixture of neon and argon gases, at a temperature of 27^@C and pressure of 1xx10^5Nm^-2 . The total mass of the mixture is 28g. If the molar masses of neon and argon are 20 and 40gmol^-1 respectively, find the masses of the individual gasses in the container assuming them to be ideal (Universal gas constant R=8.314J//mol-K ).

One mole of monoatomic gas and three moles of diatomic gas are put together in a container. The molar specific heat (in JK​^(-1)"​ mol​ "^(-1) ​) at constant volume is (R = 8.3 J K​^(-1​) " mol"​^(-1​) )