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 gram molecule of gas at 27^(@)C expands isothermally untill its volume is doubled. Find the amount of work done and heat absorbed. Take R=8.31J mol e^(-1) K^(-1) .

Three moles of an ideal gas at 127^(@)C expands isothermally untill the volume is doubled. Calculate the amount of work done and heat absorbed.

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))

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 .

If x mole of ideal gas at 27^(@)C expands isothermally and reversibly from a volume of y to 10 y, then the work done is

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)