At `27^(@)C` latent heat of fusion of a compound is `2.7 xx 10^(3)J mol^(-1)`. Calculate the entropy change during fusion

Latent heat of fusion of ice is 6 kJ mol^(-1) . Calculate the entropy change in the fusion of ice.

The entropy change for vaporisation of a liquid is 109.3 JK^(-1)mol^(-1) . The molar heat of vaporisation of that liquid is 40.77kJ mol^(-1) . Calculate the boiling point of that liquid.

Calculate the heat required to convert 3 kg of ice at -12 ^(@) C kept in a calorimeter to steam at 100^(@) C at atmospheric pressure. Given specific heat capacity of ice = 2100 J kg^(-1) K^(-1) , specific heat capacity of water = 4186 J kg^(-1) K^(-1) , latent heat of fusion of ice = 3.35 xx 10^(5) J kg^(-1) and latent heat of steam = 2.256 xx 10^(8) J kg^(-1) .

The thermodynamic property that measures the extent of molecular disorder is called entropy. The direction of a spontaneous process for which the energy is constant is always the one that increases the molecular disorder. Entropy change of phase transformation can be calculated using Trouton's formula (DeltaS= (DeltaH)/(T)) . In the reversible adiabatic process, however, DeltaS will be zero. The rise in temperature in isobaric and isochoric conditions is found to increase the randomness or entropy of the system. DeltaS= 2.303 C log (T_(1)//T_(2)), (C = C_(P) or C_(V)) The melting point of a solid is 300K and its latent heat of fusion is 600 cal mol^(-1) . The entropy change for the fusion of 1 mole of the soli (in cal K^(-1) ) at the same temperature would be:

Assume that heat capacity of H_(2) O to be 4.2 xx 10^(3) J kg ^ (-1) K^(-1) and the latent heat of vapourisation of H_(2) O to be 22.5 xx 10^(5) J kg^(-1) . The amount of heat in joule required to heat 1 kg of water from 50^(@)C to 100^(@)C and then to convert into steam at 100^(@)C is

For a liquid, enthalpy of fusion is 1.435 xx 10^(3) cal mol^(-1) and molar entropy change is 5.26 cal mol^(-1) . Calculate the melting point of the liquid.