A sample of gas `(gamma = 1.5)` is taken through an adiabatic process in which the volume is compressed from `1600 cm^(3) to 400 cm^(3)`. If the initial pressure is `150 kPa`, (a) what is the final pressure and (b) how much work is done by the gas in the process?

A given sample of an ideal gas (gamma = 1.5 ) is compressed adiabatically from a volume of 150 cm ^(3) to 50 cm ^(3) . The initial pressure and the initial temperature are 150 kpa and 300K . Find (a) the number of moles of the gas in the sample, (b) the molar heat capacity at constant volume.

1 liter of an ideal gas (gamma =1.5) at 300k is suddenly compressed to half its original volume. (a) Find the ratio of the final pressure to the initial pressure. (b) If the original pressure is 100 kpa , find the work done by the gas in the process. (c) What is the change in internal energy? (d) What is the final temperature? (e) the gas is now colled to 300k keeping its pressure constant. Calculate the work done during the process . (f) The gas is now expanded iasothermally to achive its original volume of 1 liters. Calculate the work done by the gas .(g) Calculate the total work done in the cycle.

A gas with specific heat ratio gamma = 5/3 is compressed suddenly to 1/8 of its initial volume. If the pressure is P, then the final pressure is :

The internal energy of a gas is given by U=1.5pV . It expands from 100 cm^(3) to 200 cm^(3) against a constant pressure of 1.0xx10^(5) Pa. calculate the heat absorbed by the gas in the process.

An ideal gas at pressure 2.5 xx 10^(5) pa and temperature 300k occupies 100 cc. It is adiabatically compressed to half its original volume. Calculate (a) the final pressure, (b) the final temperature and ( c) the work done by the gas in the process. Take (gamma = 1.5) .

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 the initial pressure is

The volume of an ideal gas (gamma = 1.5 ) is changed adiabatically from 4.00 liters to 3.00 liters . Find the ratio of (a) the final pressure to the initial pressure and (b) the final temperature to the initial temperature.

An ideal gas (C_p // C_V = (gamma) is taken through a process in which the pressure and the volume vary as P = aV^b . Find the values of (b) for which the specific heat capacity of the gas for the process is zero.

An ideal gas (gamma = 1.67 ) is taken through the process abc shown in figure . The temperature at the point a is 300 k . Calculate (a) the temperature at b and c, (b) the work done in the process.