The critical constants for water are `374^(@)C`, 218 atm and 0.0566 litre `mol^(-1)`. Calculate `a' and `b' of water

The critical constant for water are 374^@C , 218 atm and 0.0566 L mol^(-1) . Calculate a, b and R.

The temperature of 1 mol of an ideal monoatomic gas at constant pressure of 1 atm changes from 25^(@)C and 50^(@)C . Calculate Delta U and Delta H in this process, (C_(V)=(3)/(2)R) .

Calculate (1) the enthalpy change in the fusion of 100 g ice at 0^(@)C temperature and 1 atm pressure pressure (2) the enthalpy change in the vaporisation of 10g water at 100^(@)C temperature and 1 atm pressure. Givenn : Latent heat of ice at 0^(@)C temperature and 1 atm pressure =6.02kJ*mol^(-1) and latent heat of vaporisation of water at 100^(@)C temperature= 40.4kJ*mol^(-1) .

Vanderwaal's constants for hydrogen chloride gas are a = 3.67 atm lit^(-2) and b = 40.8 ml mol^(-1) . Find the critical temperature and critical pressure of the gas.

Heat of combustion of benzene is xJ *mol^(-1) . Heat of formation of carbon dioxide and water are yJ*mol^(-1) and zJ*mol^(-1) respectively. Calculate the heat of formation of benzene.

Heat of combustion of benzene is x J * mol^(-1) . Heat of formation of carbon dioxide and water are y J * mol^(-1) and z J * mol^(-1) respectively . Calculate the heat of formation of benzene .

If water vapour is assumed to be a perfect gas and molar enthalpy change for vapourisation of 1 mole of water at 1 bar & 100^@C is 41 kJ mol^-1 , calculate the intenal energy change when 1 mol of water is vapourised at 1 bar pressure & 100^@C

If water vapour is assumed to be a perfect gas and molar enthalpy change for vapourisation of 1 mole of water at 1 bar & 100^@C is 41 kJ mol^-1 , calculate the intenal energy change when 1 mol of water is converted into ice.

The enthalpy change for the transition of liquid water to steam is 40.8KJ mol^(-1) at 373 K calculate the entropy of evaporation of water.