Work done to increase the temperature of one mole of an odeal gas by `30^@C`, if it is expanding under the condition `V prop T^(2//3)` is , `( R = 8.314 J// mol//K)`

Work done by 0.1 mole of gas at 27^(@)C when it expands to double its volme at constant pressure is (assume R = 2 cal//mol-K )

H calories of heat is required to increase the temperature of one mole of monoatomis gas from 20^(@)C" to "30^(@)C at const. volume. The quantity of heat required to increase the temperature of 2 moles of a diatomic gas from 20^(@)C" to "25^(@)C is at constant volume is

At 27^(@)C , two moles of an ideal mono-atomic gas occupy a volume V. The gas expands adiabatically to a volume 2V. Calculate (a) final temperature of the gas (b) change in its internal energy and (c ) the work done by the gas during the process. (R = 8.31 J/mol K)

One mole of an ideal gas expands at a constant temperature of 300 K from an initial volume of 10 litres to a final volume of 20 litres. The work done in expanding the gas is (R=8.31J/mole-K)

294 joules of heat are required to rise the temperature of 2 mole of an ideal gas at constant pressure from 30^(@)C to 35^(@)C . The amount of heat required to rise the temperature of the same gas through the same range of temperature at constant volume (R = 8.3 Joules/mole/K) is

Calculate work done when 1 mole of an ideal gas is expanded reversibly from 20 L to 40 L at a constant temperature of 300 K.

Five moles of hydrogen initially at STP is compressed adiabatically so that its temperature becomes 673 K. The increase in internal energy of the gas , in kilo joule is (R= 8.3 J // mol-K, gamma = 1.4 for diatomic gas)