One gram 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 on the gas will be `(R=8.30 " J mol"^(-1)k^(-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

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

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

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

One mole of and ideal monoatomic gas is compressed isothermally in a rigid vessel to double its pressure at room temperature, 27^(@)C . The work done on the gas will be :

Five moles of hydrogen (gamma = 7//5) , initially at STP , is compressed adiabatically so that its temperature becomes 400^(@)C . The increase in the internal energy of the gas in kilojules is (R = 8.30 J//mol-K)

50g of oxygen at NTP is compressed adiabatically to a pressure of 5 atmosphere. The work done on the gas, if gamma =1.4 and R = 8.31 J mol^(-1)K^(-1) is

300K a gas (gamma = 5//3) is compressed adiabatically so that its pressure becomes 1//8 of the original pressure. The final temperature of the gas is :

A monoatomic gas is compressed adiabatically to 8/27 of its initial volume, if initial temperature is 27^° C, then increase in temperature

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)