One mole of argon is expanded according to process equation `PV^(1.5)=`constant and its temperature falls by 26 K, then

An ideal gas mixture filled inside a balloon expands according to the relation expands according to the relation PV^(2//3)= constant. What will be the temperature inside the balloon

An ideal gas expands according to the law PV^(3//2) =constant We conclude that

An ideal gas mixture filled inside a balloon expands according to relation PV^(1/2) constant. The temperature of the gas inside the balloon is:

On mole of argon expands polytropically, the polytropic constant being 1.5, that is, the process proceeds according to the law pV^(1.5) = constant. In the process, its temperature change by Delta T = - 26 K . Find a. the amount of heat obatined by the gas. b. the work performed by the gas.

An ideal gas undergoes an adiabatic process obeying the relation PV^(4//3) = constant. If its initial temperature is 300 K and then its pressure is increased upto four times its initial value, then the final temperature (in Kelvin):

In the process pV^2= constant, if temperature of gas is increased, then

One mole of an ideal gas at temperature T_ expands slowly according to the law p/V= constant. Its final temperature is T_2 . The work done by the gas is

A diatomic ideal gas is expanded according to PV^(3) = constant, under very high temperature (Assume vibration mode active). Calculate the molar heat capacity of gas (in cal / mol K) in this process.

In a process, temperature and volume of one mole of an ideal monoatomic gas are varied according to the relation VT= K, where K is a constant. In this process the temperataure of the gas is increased by DeltaT . The amount of heat absorbed by gas is (R is gas constant).