A sample of an ideal gas with initial pressure 'P' and volume 'V' is taken through an isothermal process during which entropy change is found to be DS. The work done by the gas is

The pressure P and volume V of an ideal gas both decreases in a process.

One mole of an ideal diatomic gas is taken through a process whose P-V diagram is shown in the figure. The work done by the gas is

The pressure p and volume V of an ideal gas both increase in a process.

Change in internal energy in an isothermal process for ideal gas is

The change in internal energy of two moles of a gas during adiabatic expansion is found to be -100 Joule. The work done during the process is

Conider a given sample of an ideal gas (C_p / C_v = gamma ) having initial pressure (p_0) and volume (V_0) . (a) The gas is isothermally taken to a pressure (P_0 / 2 ) and from there adiabatically ta a pressure (p_0 / 2) and from there isothermally to a pressure (p_0 / 4 ) . find the volume.

The state of an ideal gas is changed through an isothermal process at temperature T_0 as shown in figure. The work done by the gas in going from state B to C is double the work done by gas in going from state A to B. If the pressure in the state B is (p_0)/(2) , then the pressure of the gas in state C is

The state of an ideal gas is changed through an isothermal process at temperature T_0 as shown in figure. The work done by the gas in going from state B to C is double the work done by gas in going from state A to B. If the pressure in the state B is (p_0)/(2) , then the pressure of the gas in state C is

In a process, the pressure of an ideal gas is proportional to square of the volume of the gas. If the temperature of the gas increases in this process, then work done by this gas

P_(i), V_(i) are initial pressure and volumes and V_(f) is final volume of a gas in a thermodynamic process respectively. If PV^(n) = constant, then the amount of work done by gas is : (gamma = C_(p)//C_(v)) . Assume same, initial states & same final volume in all processes.