For an ideal gas of fixed amount, the initial pressure and volume are equal to the final pressure and volume

An ideal gas has an initial pressure of 3 pressure units and an initial volume of 4 volume units. The table gives the final pressure and volume of the gas (in those same units) in four processes. Whish process starts and ends on the same isotherm ltimg src="https://d10lpgp6xz60nq.cloudfront.net/physics_images/ALN_PHY_R04_E09_009_Q01.png" width="80%"gt

Two gases have the same initial pressure, volume and temperature. They expand to the same final volume, one adiabatically and the other isothermally

Can volume stress be a pressure ?

Calculate the work done when one mole of a perfect gas is compressed adiabatically. The initial pressure and volume of the gas are 10^5 N//m^2 and 6 litres respectively. The final volume of the gas are 2 litre . Molar specific heat of the gas at constant volume is 3R//2 .

Give the relationship between pressure and volume in an adiabatic process for an ideal gas.

Consider two containers A and B containing identical gases at the same pressure, volume and temperature. The gas in container A is compressed to half of its original volume isothermally while the gas in container B is compressed to half of its original value adiabatically. The ratio of final pressure of gas in B to that of gas in A is

An ideal gas having initial pressure p, volume V and temperature T is allowed to expand adiabatically until its volume becomes 5.66V, while its temperature falls to T//2 . (a) How many degrees of freedom do the gas molecules have? (b) Obtain the work done by the gas during the expansion as a function of the initial pressure p and volume V. Given that (5.66)^0.4=2

For an ideal gas PT^(11) = constant then volume expansion coefficient is equal to :-