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

The value of C_(p) - C_(v) is 1.09R for a gas sample in state A and is 1.00R in state B . Let A_(A),T_(B) denote the temperature and p_(A) and P_(B) denote the pressure of the states A and B respectively. Then

For a gas C_(P)-C_(V)=R in a state P and C_(P)-C_(V)=1.10 R in a state Q, T_(P) and T_(Q) are the temperatures in two different states P and Q respectively. Then

In the P - V diagram, the point B and C correspond to temperatures T _(1) and T_(2) respectively. State relationship between T_(1) and T_(2).

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.

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 van der Waal's equation of state for some gases can be expressed as : (P + (a)/( V^(2))) ( V - b) = RT Where P is the pressure , V is the molar volume , and T is the absolute temperature of the given sample of gas and a, b , and R are constants. The dimensions of constant b are

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.