The enthalpy change for the evaporation of a liquid at its boiling point `127^(@)C` is `+ 40.32 k J mol^(-1)`. What is the volume of internal energy change for the above process at `127^(@)C` ? `(R = 8.3 JK^(-1) mol^(-1))`

The enthalpy change for the conversion of liquid water to steat is '40.8 k J' at '100^circ C'. Calculate 'Delta S' for the process.

Enthalpy of vapourisation of liquid water is 41 kJ mol^(-1) at 373 K. The change of internal energy when 1mole water at 373 K is converted to steam at 373 K is

Calculate the volume occupied by 8.8 g of CO_2 at 31.1°C and 1 Bar pressure ( R= 0.083 Bar L K^(-1) mol^(-1) )

Molar enthalpy change for vapourisation of 1 mol of water at 100^@C and 1 bar pressure is 41 kJ mol^-1 . Assuming water vapour to be a perfect gas, calculate the internal energy change when (i) 1 mol of water is vapourised at 1 bar pressure and 100^@C

Molar enthalpy change for vapourisation of 1 mol of water at 100^@C and 1 bar pressure is 41 kJ mol^-1 . Assuming water vapour to be a perfect gas, calculate the internal energy change when (ii) 1 mol of water is converted to ice

Enthalpy of vaporisation of benzene is 30.8 kJ mol" at its normal boiling point of 80^(@)C. Time required for a 100 W electric heater to vapourise 100 g benzene at its boiling point (Given 1W = 1 Js^(-1) )