If `Q` amount of heat is given to a diatomic ideal gas in a process in which the gas perform a work `(2Q)/(3)` on its surrounding. Find the molar heat capacity (in terms of `R`) for the process.

An amount of heat is added to a monatomic ideal gas in a process in which the gas performs work Q/2 on its surrounding. Find the molar heat capacity for the process.

An amount of heat is added to a monatomic ideal gas in a process in which the gas performs work Q/2 on its surrounding. Find the molar heat capacity for the process.

An amount Q of heat is added to a mono atomic ideal gas in a process in which the gas performs a work Q//2 on its surrounding. Find equation of the process.

(a) A polytropic process for an ideal gas is represented by PV^(x) = constant, where x != 1 . Show that molar specific heat capacity for such a process is given by C = C_(v) + (R)/(1-x) . (b) An amount Q of heat is added to a mono atomic ideal gas in a process in which the gas performs a work (Q)/(2) on its surrounding. Show that the process is polytropic and find the molar heat capacity of the gas in the process.

600 J of heat is added to a monatomic gas in a process in which the gas performs a work of 150 J . The molar heat capacity for the process is KR . Then find K .

600J of heat is added to a monoatomic gas in a process in which the gas performs a work of 150J. The molar heat capacity for the process is

600J of heat is added to a monoatomic gas in a process in which the gas performs a work of 150J. The molar heat capacity for the process is

"600J" of heat is added to a monatomic gas in a process in which the gas performs a work of "150J" .The molar specific heat capacity of the gas for the process is

The molar heat capacity of a gas in a process

An ideal diatomic gas undergoes a process in which the pressure is proportional to the volume. Calculate the molar specific heat capacity of the gas for the process.