Two samples A and B are initaially kept in the same state. The sample A is expanded through an adiabatic process and the sample B through an isothermal process. The final volumes of the samples are the same . The final pressures in A and B are `p_A and P_B` respectively.

Two samples 1 and 2 are initially kept in the same state. The sample 1 is expanded through an isothermal process where as sample 2 through an adiabatic process upto the same final volume. The final temperature in process 1 and 2 are T_(1) and T_(2) respectively, then

Two samples 1 and 2 are initially kept in the same state. The sample 1 is expanded through an isothermal process where as sample 2 through an adiabatic process upto the same final volume. The final temperature in process 1 and 2 are T_(1) and T_(2) respectively, then

Two samples 1 and 2 are initially kept in the same state. The sample 1 is expanded through an isothermal process where as sample 2 through an adiabatic process upto the same final volume. The final temperature in process 1 and 2 are T_(1) and T_(2) respectively, then

two samples 1 and 2 are initially kept in the same state. the sample 1 is expanded through an isothermal process where as sample 2 through an adiabatic process up to the same final volume.Let p_(1) and p_(2) be the final pressure of the samples and 2 respectively in the previous question then.

Two samples A and B are initially kept in the same state. The sample B through an isothermal process. The final volumes of the samples are the same (a) Compare final temperatures, final pressures and work doen in A and B. (b) Repeat the part (i), If samples are compressed to same final volume.

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.

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.

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.

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.