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`)

An ideal gas with pressure P , volume V and temperature T is expanded isothermally to a volume 2V and a final pressure P_i . If the same gas is expanded adiabatically to a volume 2V , the final pressure is P_a . The ratio of the specific heats of the gas is 1.67 . The ratio of P_a / P_i is ........

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.

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

Two samples A and B of the same gas have equal volumes and pressures . The gas is sample A is expanded isothermally to double its volume and the the gas in B is expanded adibatically to double its volume . If the work done by the gas is the same for the two cases, show that gamma satisfies the equation (1-2 ^(1-gamma)= (gamma - 1 ) 1n2 .

Helium at 27°C has a volume of 8 litres. lt is suddenly compressed to a volume of 1 litre. The temperature of the gas will be [Take, gamma =5/3].

Conider a given sample of an ideal gas (C_p / C_v = gamma ) having initial pressure (p_0) and volume (V_0) . (a) The gas is isothermally taken to a pressure (P_0 / 2 ) and from there adiabatically ta a pressure (p_0 / 2) and from there isothermally to a pressure (p_0 / 4 ) . find the volume.

The pressure p and volume V of an ideal gas both increase in a process.

If the internal energy of an ideal gas U and volume V are doubled, then the pressure of the gas :