The temperature of 5 moles of a gas at constant volume is changed from `100^(@)C` to `120^(@)C`. The change in internal energy is 80 J. The total heat capacity of the gas at constant volume will be in `J/K.`

The temperature of 5 mol of gas which was held at constant volume was change from 100^(@)C to 120^(@)C . The change in internal energy was found to ve 80 J . The total heat capacity of the gas at constant volume will be equal to

The temperature of 5 mol of gas which was held at constant volume was change from 100^(@)C to 120^(@)C . The change in internal energy was found to be 80 J . The total heat capacity of the gas at constant volume will be equal to

The temperature of 5 mol of gas which was held at constant volume was change from 100^(@)C to 120^(@)C . The change in internal energy was found to ve 80 J . The total heat capacity of the gas at constant volume will be equal to

The temperature of 5 mol of gas which was held at constant volume was change from 100^(@)C to 120^(@)C . The change in internal energy was found to have 80 J . The total heat capacity of the gas at constant volume will be equal to

When the temperature of 4 moles of a gas was increased from 80^(@)C to 100^(@)C , at constant volume, the change in internal energy was 60J. What is the total heat capacity of the gas at constant volume ?

When the temperature of 5 mol of a gas is changed from 100^@C to 120^@C keeping the volume constant, the change in internal energy of the gas is 80 J, then find the heat capacity of the gas at constant volume.

5 mol of oxygen is heated at constant volume from 10^@C to 20^@C . Find the change in internal energy of the gas