A gas originally at `1.10atm` and `298K` underwent a reversible adiabatic expansion to `1.00atm` and `287K`. What is the molar heat capacity of the gas?

A perfect gas undergoes a reversible adiabatic expansion from (300 K, 200 atm) to (90 K, 10 atm). Find the atomicity of gas.

9.00 litres of a gas at 16 atm and 27°C weigh 93.6 g. What is the molecular mass of the gas ?

1 mole of an ideal gas undergoes an isothermal reversible expansion form 10 atm to 1 atm at 300 K. What will be the work done ?

14 g oxygen at 0^(@)C and 10 atm is subjected to reversible adiabatic expansion to a pressure of 1atm . Calculate the work done in a. Litre atomsphere. b. Calorie (given, C_(P)//C_(V) = 1.4) .

14 g oxygen at 0^(@)C and 10 atm is subjected to reversible adiabatic expansion to a pressure of 1atm . Calculate the work done in a. Litre atmosphere. b. Calorie (given, C_(P)//C_(V) = 1.4) .

One mol of an ideal diatomic gas underwent an adiabatic expansion form 298K, 15.00atm , and 5.25L to 2.5atm against a constant external pressure of 1.00atm . What is the final temperature of the system?

A sample of 3.0 mole of perfect gas at 200 K and 2.0 atm is compressed reversibly and adiabatically until the temperature reaches 250 K . Given that molar heat capacity at 27.5 J K^(-1) mol^(-1) at constant volume calculate q,W,DeltaU,DeltaH and the final pressure and volume.

10 moles of a gas are heated at constant volume from 20^@C" to "30^@C . Calculate the change in the internal energy of the gas. The molar heat capacity of the gas at constant pressure, C_p = 6.82 cal K^(-1) mol^(-1) and R = 1.987 cal K^(-1) mol^(-1) .

P-V diagram of a diatomic gas is a straight line passing through origin. The molar heat capacity of the gas in the process will be

P-V diagram of a diatomic gas is a straight line passing through origin. The molar heat capacity of the gas in the process will be