One mole of ideal gas `(C_(V)="20 JK"^(-1)"mol"^(-1))` initially at STP is heated at constant volume to twice the initial temperature. For the process, W and q will be -

One mole of an ideal gas ( C_(V) = 20 JK^(-1) mol^(-1)) initially at STP is heated at constant volume to twice the initial temeprature. For the process W and q will be

One mole of ideal gas (C_(P, m) = 15 JK^(-1) "mole"^(-1)) follow the process as shown in figure.

When one mole of an ideal gas is compressed to half of its initial volume and simultaneously heated to twice its initial temperature, the change in entropy of gas (DelataS) is:

One mole of an ideal gas at an initial temperature true of TK does 6R joule of work adiabatically. If the ratio of specific heats of this gas at constant pressure and at constant volume is 5//3 , the final temperature of the gas will be

One mole of an ideal gas at an initial temperature true of TK does 6R joule of work adiabatically. If the ratio of specific heats of this gas at constant pressure and at constant volume is 5//3 , the final temperature of the gas will be

Initially one mole of ideal gas (C_(v)=(5)/(2)R) at 0.1 atm and 300 K is put through the following cycle: Step-I : Heating to twice its initial pressure at constant volume. Step-II : Adiabatic expansion to its initial temperature. Step-III : Isothermal compression back to 1.00 atm. what is the volume at state X?

A given sample of an ideal gas (gamma = 1.5 ) is compressed adiabatically from a volume of 150 cm ^(3) to 50 cm ^(3) . The initial pressure and the initial temperature are 150 kpa and 300K . Find (a) the number of moles of the gas in the sample, (b) the molar heat capacity at constant volume, (c) the final pressure and temperature, (d) the work done by the gas in the process and (e) the change in internal energy of the gas .

Three moles of an ideal gas (C_p=7/2R) at pressure, P_A and temperature T_A is isothermally expanded to twice its initial volume. It is then compressed at constant pressure to its original volume. Finally gas is compressed at constant volume to its original pressure P_A . (a) Sketch P-V and P-T diagrams for the complete process. (b) Calculate the net work done by the gas, and net heat supplied to the gas during the complete process.

Forty calories of heat is needed to raise the temperature of 1 mol of an ideal monatomic gas from 20^(@)C to 30^(@)C at a constant pressure. The amount of heat required to raise its temperature over the same interval at a constant volume (R = 2 cal mol^(-1) K^(-1)) is

One mole of an ideal monoatomic gas requires 207 J heat to raise the temperature by 10 K when heated at constant pressure. If the same gas is heated at constant volume to raise the temperature by the same 10 K, the heat required is [Given the gas constant R = 8.3 J/ mol. K]