One mole of an ideal diatomice gas undergoes a transition from AtoB along a path AB as shown in the figure,The change in the internal energy of the gas during the tranition is :

The change in internal energy when a gas is cooled from 927°C to 27°C is

One mole of an ideal gas with gamma = 1.4 , is adiabatically compressed so that its temperature rises from 42°C to 48°C . The change in the internal energy of the gas is ( R = 8.3 J / mol / K )

Calculate the internal energy of 1 mole of an ideal gas at 250ºC.

During an adiabatic expansion of 2 moles of a gas, the change in internal energy was found -50 J. The work done during the process is

One mole of an ideal monoatomic gas undergoes a process described by the equation PV^3 = constant. The heat capacity of the gas during this process is

An ideal gas goes from the state i to the state int as shown in .the work done by the gas during the process

An adiabatic vessel of total volume V is divided into two equal parts by a conducting separator. The separator is fixed in this position. The part on the left contains one mole of an ideal gas (U=1.5 nRT) and the part on the right contains two moles of the same gas. initially, the pressure on each side is p. the system is left for sufficient time so that a steady state is reached. find (a) the work done by the gas in the left part during the process, (b) the temperature on the two sides in the beginning, (c ) the final common temperature reached by the gases, (d) the heat given to the gas in the right part and (e) the increase in the internal energy of the gas in the left part.

A gas is taken along the path AB as shown in fig, if 70 cal of heat is extracted from the gas in the process, calculate the change in the internal energy of the system.

One mole of an ideal gas (gamma=1.4) is compressed adiabatically , so that its temperature is increased from 27^@ C " to " 35^@C If R = 8.31 J/K/mole then the change in the internal energy of the gas is :