Three samples `A`, `B` and `C` of the same gas `(gamma = 1.5)` have equal volumes and temperatures. The volume of each sample is doubled, the process being isothermal for `A`, adiabatic for `B` and isobaric for `C`. If the final pressures are equal for the three samples, Find the ratio of the initial pressures.

Three samples of the same gas A,B and C (gamma=3//2) have initially equal volume. Now the volume of each sample is doubled. The process is adiabatic for A. Isobaric for B and isothermal for C. If the final pressures are equal for all three samples, find the ratio of their initial pressures

Three identical diatomic gases ( gamma =1.5) are enclosed in three identical containers but at different pressures and same temperatures. These gases are expanded to double their volumes in first container the process is isothermal, in second container the process is adiabatic and in third container process is isobaric. Of The final pressures are equal in the three containers, find the ratio of the initial pressures in the three containers.

Three samples of the same gas 'x','y' and 'z', for which the ratio of specific heats in gamma=3//2 , have initially the same volume. The volumes of each sample is doubled, by adiabatic process in the case of 'x' by isobaric process in the case of 'y' and by isothermal process in the case of 'z'. If the initial pressures of the samples 'x','y' and 'z' are in the ratio 2sqrt(2):1:2 , then the ratio of theri final pressures is

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

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 .

Two samples A and B of the same gas have equal volumes and pressure. The gas in sample A is expanded isothermally to four times of its initial volume and the gas in B is expanded adiabatically to double its volume. It work done in isothermal process is twice that of adiabatic process, then show that gamma satisfies the equation 1-2^(1-gamma) =(gamma-1)In2 .

A sample of an ideal gas in a cyclinder is compressed adiabatically to 1/3rd of its volume. Will final pressure be more or less than 3 times the initial pressure?

A gas for which gamma=1.5 is suddenly compressed to 1//4 th of the initial volume. Then the ratio of the final to initial pressure is