The internal energy of a gas is given by `U=2pV`. It expands from `V_0` to `2V_0` against a constant pressure `p_0`. The heat absorbed by the gas in the process is

The internal energy of a gas is given by U = 3 pV. It expands from V_(0) to 2V_(0) against a constant pressure p_(0) . The heat absorbed by the gas in the process is

The internal energy of a gas is given by U= 5 + 2PV . It expands from V_(0) to 2V_(0) against a constant pressure P_(0) . The heat absorbed by the gas in the process is :-

The internal energy of a gas is given by U = 3 pV. It expands from V_(0) to 2V_(0) against a constant pressure p_(0) . What is the value of gamma(=C_(P)//C_(V)) for the given gas?

The internal energy of a gas is given by U=1.5pV . It expands from 100cm^2 to 200cm^3 against a constant pressure of 1.0xx10^5Pa . Calculate the heat absorbed by the gas in the process.

The internal energy of a gas is given by U=1.5pV. It expandeds 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.

A diatomic gas with rigid molecules does 10J of work when expanded at constant pressure. The heat energy absorbed by the gas, in this process is ___________ (in J).

If the internal energy of an ideal gas varies as U = 2PV and the gas undergoes an expansion as shown below, then heat absorbed in the process will be :

The internal energy of an ideal diatomic gas corresponding to volume V and pressure P is U = 2.5 PV . The gas expands from 1 litre to 2 litre at a constant pressure of one atmosphere. The heat supplied to gas is

Figure shows the variation of internal energy (U) with the pressure (P) of 2.0 mole gas in cyclic process abcda.The temperature of gas at c and d are 300 and 500 K respectively. The heat absorbed by the gas during the process is Xxx 10 R ln 2 . Find the value of x.

Pressure and volume of a gas changes from (p_0V_0) to (p_0/4, 2V_0) in a process pV^2= constant. Find work done by the gas in the given process.