Suppose 2.00 mol of an ideal gas is contained in a heat-insulated cylinder with a moveable frictionless piston. Initially the gas is at 101 kPa and 0^oC. The gas is compressed reversibly to 202 kPa. The molar heat capacity at constant pressure, c_p, equals 29.3 J/(mol.K). Calculate the final temperature of the gas, the change in its internal energy and the work done on the gas. ??

Nitrogen gas is contained in a piston and cylinder device with a free-floating piston. Initially, the gas is 27 degree C and occupies a volume of 0.18 m^3 at a pressure of 500 kPa. The gas is slowly heated until the temperature is 400 degree C, while the pressure remains constant. For nitrogen: Determine: a. The amount of heat added to the piston. b. The work done during this process. The piston reaches a barrier once T = 400 degree C and can no longer expand. However, the gas is heated until the temperature reaches 1000 degree C. Determine: c. The amount of heat added to the system. d. The work done during the process With the temperature still at 1000 degree C, the system is placed inside a well-insulated container. The piston is compressed to one half of its volume. Find: e. The work done on the piston. f. The temperature of the gas after compression.

For an ideal gas at STP (T_0 = 273. 15 K, P_0 = 101. 3 kPa), C_P = 3. 5R. Determine the numerical value for its molar or specific volume V. the final pressure P_1 if the air is compressed during the adiabatic process (constant heat capacity) from STP to a final state of T_1 = 353. 15 K. The work W for (b) (assuming 1 mol of ideal gas).