At `0^(@)C` water and ice are at equilibrium at `1` atm pressure. The value of `DeltaH_("fusion")` for ice is `("in kJ/mole").` Give answer excluding decimal places.
Given: `DeltaS_("freezing")` of water at `1` atm and `273` K is `-20JK^(-1))`

For reversible melting of ice at 0^(@)C and 1 atm. Pressure, the value of Delta G will be :-

At 0^(@)C ice and water are in equilibrium and DeltaH=6kJ" "mol^(-1) for this process: H_(2)OhArrH_(2)O(l) The values of DeltaS and DeltaG for conversion of ice into liquid water at 0^(@)C are:

Volume of 0.5 mole of a gas at 1 atm. Pressure and 273 K is

1 mole of H_(2)O is vaporised at 100^(@)C and 1 atm pressure. If the latent heat of vaporisation of water is x J/g, then Delta S in terms of J/mole K is given by

The enthalpy of fusion of water is 1.435 kcal//"mole" . The molar entropy change for melting of ice at 0^(@)C is

Calculate the entropy change accompanying the conversion of 1 mole of ice at 273.1 K and 1 atm pressure into steam at 373.1 K and 1 atm pressure. At 273.1 K, the molar heat of fusion of ice, DeltaH_(f) is 6.00 kJ mol^(-1) and at 373.1 K, the molar heat of vapourization of water, DeltaH_(v) , is 40.6 kJ mol^(-1) . Also assume that the molar heat capacities, C_(p) , in the temperature range 373.1 to 273.1 K remains constant. Given that C_(p) = 75.25 m mol^(-1)K^(-1) and log 13.66 = 1.1354.