At normal temperature, one mole of diatomic gas is compressed adiabatically to half of its volume. Where, `gamma` = 1.41. The final temperature of the gas will be

A diatomic gas initially at 18°C is compressed adiabatically to one eighth of its original volume. The temperature after compression will be

A diatomic gas initially at 30°C is compressed adiabatically to one- eighth of its original volume. The temperature after compression will be

An ideal gas at a pressures of 1 atmosphere and temperature of 27°C is compressed adiabatically until its pressure becomes 8 times the initial pressure. Then, the final temperature is (Take, gamma = 3/2).

A monatomic gas at a pressure P, having a volume V expands isothermally to a volume 2V and then adiabatically to a volume 16V. The final pressure of the gas is (Take gamma = 5/3 )

A mass of ideal gas at pressure P is expanded isothermally to four times the original volume and then slowly compressed adiabatically to its original volume. Assuming gamma(=C_(P)//C_(V)) to be 1.5, find the new pressure of the gas.

An ideal gas is expanded adiabatically at an initial temperature of 300 K, so that it's volume is doubled. The final temperature of the hydrogen gas is (Take, gamma = 1.40).

An ideal gas at pressure 2.5 xx 10^(5) pa and temperature 300k occupies 100 cc. It is adiabatically compressed to half its original volume. Calculate (a) the final pressure, (b) the final temperature and ( c) the work done by the gas in the process. Take (gamma = 1.5) .

A given sample of an ideal gas (gamma = 1.5 ) is compressed adiabatically from a volume of 150 cm ^(3) to 50 cm ^(3) . The initial pressure and the initial temperature are 150 kpa and 300K . Find (a) the number of moles of the gas in the sample, (b) the molar heat capacity at constant volume.