A swimmer coming out from a pool is covered with a film of water weighing about `80g`. How much heat must be supplied to evaporate this water ? If latent heat of evaporation for `H_(2)O` is `40.79 kJ mol^(-1)` at `100^(@)C`.

A swimmer coming out from a pool is covered with a film of water weighing about 18 g. how much heat must be supplied to evaporate this water at 298 K ? Calculate the internal energy of vaperization at 100^(@)C . Delta_(vap)H^(Theta) for water at 373 K = 40.66 kJ mol^(-1)

A swimmer coming out from a pool is covered with a film of water weighing about 18 g. how much heat must be supplied to evaporate this water at 298 K ? Calculate the internal energy of vaperization at 100^(@)C . Delta_(vap)H^(Theta) for water at 373 K = 40.66 kJ mol^(-1)

How much heat is evolved if 3.2 g of methane is burnt and if the heat of combustion of methane is -880" kJ mol"^(-1) ?

Calculate the entropy change for vaporization of water if latent heat of vaporization for water is 2.26 kJ/gram. The K_(b) for H_(2)O is 0.51 K/molality

Calculate the entropy change when 3.6g of liquid water is completely converted into vapour at 100^(@)C . The molar heat of vaporization is 40.85KJ mol^(-1) .

The entropy change for vapourisation of liquid water to steam 100^@C is …. JK^(-1) mol^(-1) . Given that heat of vapourisation is 40.8 kJ mol^(-1) .

Heat energy is supplied at a constant rate to 400 g of ice at 0^@ C. The ice is converted into water at 0^@ C in 5 minutes. How much time will be required to raise the temperature of water from 0^@ C to 100^@ C ? Specific latent heat of ice = 336 J g^(-1) , specific heat capacity of water = 4.2 J g^(-1)K^(-1)

Water at 0^@C was heated until it started to boil and then until it all changed to steam. The time required to heat water from 0^@C to 100^@C is 5 min and the time to change boiling water to steam is 28 minutes. If the flame supplied heat at a constant rate, the specific latent heat of vaporization of water (neglecting heat losses, container etc. is (in J//g ). (specific heat of water s =4.2 J//g )

18g of water is taken to prepare the tea. Find out the internal energy of vaporisation at 100^(@) C. (Delta_(vap)H for water at 373 K is 40.66kJ mol^(-1))

A thermally insulated vessel contains 150g of water at 0^(@)C . Then the air from the vessel is pumped out adiabatically. A fraction of water turms into ice and the rest evaporates at 0^(@)C itself. The mass of evaporated water will be closest to : (Latent heat of vaporization of water =2.10xx10^(6)jkg^(-1) and Latent heat of Fusion of water =3.36xx10^(5)jkg^(-1) )