The molar heat capacity at constant volume of a system is 12.41J. `mol^(-1)`. In an adiabatic expansion the temperature of one mole of that gas falls from 298K to 288K. Calculate the work done by the gas.

At 400K, 5 moles of an ideal gas expands isothermally and reversibly from 10dm^3 to 20 dm^3 . Calculate the work done by the gas.

n moles of a gas expands from volume V_(1) to V_(2) at constant temperature T. The work done by the gas is

What is the value of gas constant R in J mol^(-1 ) K^(-1) ?

For an ideal gas a) The change in internal energy in a constant pressure process from temperature T_(1) to T_(2) is equal to nC_(v) (T‌_(2)-T_(1)) , where Cv is the molar heat capacity at constant volume and n is the number of moles of the gas b) The change in internal energy of the gas and the work done by the gas are equal in magnitude in an adiabatic process c) The internal energy does not change in an isothermal process d) No heat is added or removed in an adiabatic process

The molar specific heat of a gas at constant volume is 20 Joule/gm mol/K. The value of gamma for it will be