Let `T_a and T_b` be the final temperatures of the samples A and B respectively in the previous question.

Let p_(1) and p_(2) be the final pressure of the samples and 2 respectively in the previous question then.

Let (Delta W_a) and (Delta W_b) be the work done by the system A and B respectively in the previous question.

The value of (C_p - C_v) is 1.00 R for a gas sample in state A and is 1.08 R in state B. Let ( p_A, p_B) denote the pressures and (T_A and T_B) denote the temperatures of the states A and B respectively . Most likely

Figure shows variation of intensity per unit wavelength (Radiance) with wavelength for radiation coming from two source A and B. Let T_A and T_B be temperature of source A and B respectively and d_A and d_B be distance of source from detector, then–

Two different ideal diatomic gases A and B are initially in the same state. A and B are then expanded to same final volume through adiabatic and isothermal process respectively. If P_(A), P_(B) and T_(A), T_(B) represents the final pressure and temperature of A and B respectively then.

A sphere A is placed at smooth table. An another sphere B is suspended as shown in figure. Both spheres are identical in all respects. Equal quantity of heat is supplied to both spheres. All kiinds of heat loss are neglected. The final temperatures of A and B are T_(A) and T_(B) respectively, then

In an adiabatic expansion of a gas initial and final temperatures are T_(1) and T_(2) respectively, then the change in internal energy of the gas is

Temperature T_(1) and T_(3) represents respectively: