A certain volume of a gas (diatomic) expands isothermally at `20^@C` until its volume is doubled and then adiabatically until its volume is again doubled. Find the final temperature of the gas, given `gamma`= 1.4 and that there is 0.1 mole of the gas. Also calculate the work done in the two cases. `R=8.3 J "mole"^(-1) K^(-1)`

A gass of given mass at a pressure of 10^(5)Nm^(-2) expands isothermally until its volume is doubled and then adiabatically until volume is again double. Find the final pressure of the gas. (gamma=1.4)

One mole of perfect gas, initially at a pressure and temperture of 10^(5)Nm^(-2) and 300 K, respectively, expands isothermally until its volume is doubled and then adiabatically until its volume is again doubled. Find the final pressure of the gas. Given gamma=1.4 .

A gram molecule of a gas at 127^(@)C expands isothermally until its volume is doubled. Find the amount of work done and heat absorbed.

A volume of gas at 15^(@)C expands adiabatically until its volume is doubled. Find the resultant temperture given that the ratio of specific heat capacity of the gas =1.4 .

A gram mole of a gas at 27^@C expands isothermally until its volume is doubled. Calculate the amount of work done. (R=8 J mol^(-1) K^(-1))

One mole of a perfect gas, initally at a pressure and temperature of 10^(5) N//m^(2) and 300 K, respectively, expands isothermally unitl its volume is doubled and then adiabatically until its volume is again doubled. Find final pressure and temperature of the gas Find the total work done during the isothermal and adiabatic processes. Given gamma = 1.4 . Also draw the P-V diagram for the process.

An ideal gas is expanded adiabatically at an initial temperature of 300 K so that its volume is doubled. The final temperature of the hydrogen gas is lambda=1.40)