5 moles of an ideal gas at 100 K are allowed to undergo reversible compression till its temperature becomes 200 K. If `C_V = 28 JK^(-1) mol^(-1)`, calculate `DeltaU and DeltapV`.

5 moles of an ideal gas at 100 K are allowed to undergo reversible compression till its temperature becomes 200 K. If Delta U is 14 kJ, what is Delta pV in J ? for this process ( R = 8.0J K ^( -1 ) mol^( -1) )

5 moles of an ideal gas at 100 K are allowed to undergo reversible compression till its temperature becomes 200 K. If Delta U is 14 kJ, what is Delta PV for this process ( R = 8.0J K ^( -1 ) mol^( -1) )

Calculate the moles of an ideal gas at pressure 2 atm and volume 1 L at a temperature of 97.5 K

Two moles of an ideal gas at 1 atm are compressed to 2 atm at 273 K. The enthalpy change for the process is

1 mole of an ideal gas undergoes an isothermal reversible expansion form 10 atm to 1 atm at 300 K. What will be the work done ?

Two mole of an ideal gas is heated at constant pressure of one atmosphere from 27^(@)C to 127^(@)C . If C_(v,m)=20+10^(-2)"T JK"^(-1).mol^(-1) , then q and DeltaU for the process are respectively:

A sample of 3.0 mole of perfect gas at 200 K and 2.0 atm is compressed reversibly and adiabatically until the temperature reaches 250 K . Given that molar heat capacity at 27.5 J K^(-1) mol^(-1) at constant volume calculate q,W,DeltaU,DeltaH and the final pressure and volume.

n moles of an ideal triatomic linear gas undergoes a process in which the temperature changes with volume as k_(1)V ^ 2 where k_(1) is a constant. Choose incorrect alternative.

10 mole of an ideal gas is heated at constant pressure of one atmosphere from 27^(@)C to 127^(@)C . If C_(v,m)=21.686+10^(-3)T(JK^(-1).mol^(-1)) , then DeltaH for the process is :

One mole of an ideal gas is allowed to expand reversible and adiabatically from a temperatureof 27^(@)C) if the work done during the process is 3 kJ,the final temperature will be equal to (C_(v)=20JK^(-1))