An ideal gas `(gamma = 1.5)` undergoes a thermodynamic process in which the temperature and pressure of the gas are related as `T^(-1)P^(2)`= constant. The molar heat capacity of the gas during the process is

A monoatomic gas undergoes a process in which the pressure (P) and the volume (V) of the gas are related as PV^(-3)= constant. What will be the molar heat capacity of gas for this process?

A monoatomic gas undergoes a process in which the pressure (P) and the volume (V) of the gas are related as PV^(-3)= constant. What will be the molar heat capacity of gas for this process?

In a thermodynamic process on an ideal diatomic gas, work done by the gas is eta times the heat supplied (eta lt 1) . The molar heat capacity of the gas for the process is

An ideal gas undergoes a process in which its pressure and volume are related as PV^(n) =constant,where n is a constant.The molar heat capacity for the gas in this process will be zero if

In a thermodynamic process on an ideal diatomic gas, work done by the gas is eta times. The heat supplied (eta lt 1) . The molar heat capacity of the gas for the process is

One mole of an ideal monatomic gas undergoes a process described by the equation PV^(3) = constant. The heat capacity of the gas during this process is

One mole of an ideal monatomic gas undergoes a process described by the equation PV^(3) = constant. The heat capacity of the gas during this process is

An ideal gas with adiabatic exponent ( gamma=1.5 ) undergoes a process in which work done by the gas is same as increase in internal energy of the gas. Here R is gas constant. The molar heat capacity C of gas for the process is:

An ideal gas with adiabatic exponent ( gamma=1.5 ) undergoes a process in which work done by the gas is same as increase in internal energy of the gas. Here R is gas constant. The molar heat capacity C of gas for the process is: