The pressure of an ideal gas is weitten as `p=(2E)/(3V)`.Here E refers to

The pressure of an ideal gas varies according to the law P = P_(0) - AV^(2) , where P_(0) and A are positive constants. Find the highest temperature that can be attained by the gas

The pressure P and volume V of a gas are related as PV^(3//2)=K where K is a constant. The percentage increase in the pressure for a diminution of 0.5% of the volume is

Two moles of an ideal gas with (C_(P))/(C_(V))= (5)/(3) are mixed with 3 moles of another ideal gas with (C_(P))/(C_(V))= (4)/(3) . The value of (C_(P))/(C_(V)) for the mixture is

A weightless piston divides a thermally insulated cylinder into two parts of volumes V and 3V. 2 moles of an ideal gas at pressure P = 2 atmosphere are confined to the part with volume V =1 litre. The remainder of the cylinder is evacuated. The piston is now released and the gas expands to fill the entire space of the cylinder. The piston is then pressed back to the initial position. Find the increase of internal energy in the process and final temperature of the gas. The ratio of the specific heats of the gas, gamma =1.5 .

For isothermal process of an ideal gas (dP)/P = _____

The equation of state of a real gas is given by (P+a/V^(2)) (V-b)=RT where P, V and T are pressure, volume and temperature resperature and R is the universal gas constant. The dimensions of the constant a in the above equation is

The pressure (P) and absolute temperature (T) of an ideal gas are related to each other as Pprop(1)/(T^(2)) . If temperature of gas is 300 K and its volume changes from V to 8 V, then find the final temperature of gas.

Three moles of an ideal gas (C_p=7/2R) at pressure, P_A and temperature T_A is isothermally expanded to twice its initial volume. It is then compressed at constant pressure to its original volume. Finally gas is compressed at constant volume to its original pressure P_A . (a) Sketch P-V and P-T diagrams for the complete process. (b) Calculate the net work done by the gas, and net heat supplied to the gas during the complete process.