The work of 146 kJ is performed in order to compress one kilo mole of a gas adiabatically and in this process the temperature of the gas increases by `7^@C`. The gas is `(R=8.3ml^-1Jmol^-1K^-1)`

If 5 moles of oxygen at STP is adiabatically compressed so that temperature increases to 400^@C , then find the work done on the gas. R=8.3J/mole−K

The pressure of a gas in a closed vessel is increased by 0.4%, if the temperature of the gas is increased by 1^@C , the initial temperature of the gas is

A cylinder of fixed capacity 67 .2 litres contains helium gas at STP. Th~ amount of heat needed to rise the temperature of the gas in the cylinder by 20 °C is (R = 8.31 J mol^(-1)K^(-1) )

A given amount of gas is heated till the volume and pressure are each increased by 1% . Then the temperature increases by

The work done during the process when 1 mol of gas is allowed to expand into vaccum is

Calculate the temperature of 4.0 mol of a gas occupying 5 dm^3 at 3.32 bar. (R=0.083 bar dm^3 K^(-1) mol^(-1) )

5.6 liter of helium gas at STP is adiabatically compressed to 0.7 liter. Taking the initial temperature to be T_1, the work done in the process is

Work done for the rise of one mole of helium gas adiabatically through 2^@C is W. What is the work done for the rise of one mole of hydrogen gas adiabatically through 2^@C ?

Total random kinetic energy of the molecules in 1 mole of a gas at a temperature of 300 K is (R = 2 cal/mole °C)

One mole of an ideal 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 10 K, then heat required is [given gas constant. R = 8.31/(mol -K)]