In an isothermal process the specific heat is

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

(A): The specific heat of a given mass of a gas in an adiabatic process is zero and in an isothermal process is infinity. (R) : Specific heat of gas is directly proportional to change in heat of a system and directly proportional to change in its temperature.

An ideal gas of specific heat ratio gamma with volume and pressure P is compressed to increase the pressure by DeltaP . If the change in volume is Delta V_1 in an isothermal process and Delta V_2 in an adiabatic process, then

(A): The internal energy of an ideal gas does not change during an isothermal process (R ): In isothermal process product of pressure and volume is constant.

Consider a cycle followed by an engine 1 to 2 is isothermal 2 to 3 is adiabatic 3 to 1 is adiabatic such a process does not exist because a) heat is completely converted to mechanical energy in such a process, which is not possible b) mechanical energy is completely converted to heat in this process, which is not possible c) curves representing two adiabatic processes don't intersect d) curves representing an adiabatic process and an isothermal process don't intersect