One mole of an ideal gas `(gamma=7//5)` is adiabatically compressed so that its temperature rises from `27^(@)C` to `35^(@)C` the work done by the gas is (R=8.47J/mol-K)

One mole of an ideal gas with gamma=1.4 is adiabatically compressed so that its temperature rises from 27^(@)C to 34^(@)C . The change in the internal energy of the gas is (R=8.3J mol^(-10k^(-1)))

One gm mol of a diatomic gas (gamma=1.4) is compressed adiabatically so that its temperature rises from 27^(@)C to 127^(@)C . The work done will be

Two moles of an ideal monatomic gas is heated at constant pressure so that its temperature increases from 127^° C to 227^° C , then work done by gas

A mole of a monatimic perfect gas is adiabatically comporessed when its temperature rises from 27^(@) to 127^(@)C . Calculate the work done. [Hint: Work done =R(T-T')/gamma-1, for monatomic gas = 5/3 ]

One cubic metre of argon at 27^(@)C is adiabatically compressed so that the final temperature is 127^(@)C . Calculate the new volume of the gas (gamma=5//3) .

One mole of an ideal gas is taken through an adiabatic process where the temperature rises from 27^(@)C to 37^(@)C . If the ideal gas is composed of polyatomic molecule that has 4 vibrational modes, which of the following is true ? [R=8.314" J mol"^(-1)k^(-1)]

A mass of diatomic gas (gamma=1.4) at a pressure of 2 atomphere is compressed adiabitically so that its temperature rises from 27^(@)C to 927^(@)C . The pressure of the gas in the final state is

A cylinder containing one gram molecule of the gas was compressed adiabaticaly untill its tempertaure rose from 27^(@)C to 97^(@)C . Calculate the work done and heat produced in the gas (gamma=1.5) .