Water of mass `m=1kg` and `M` (mol mass) `=18` turns completely into saturated vapour at standard atmospheric pressure. Assuming the saturated vapour to be an ideal gas find increment of internal energy of the system. Specific latent heat of steam is `L=2550kJ//kg`

1 kg mass of water, bolts at standard atmosphere pressure, turns completely into saturated vapour. Assume saturated vapour to be an ideal gas. Find the increment of internal energy of the system and internal work done. (Given, specific latent heat of avporisation of water=2250kJ/kg)

An amount of water of mass m = 1.00 kg , boiling at standard atmospheric pressure, turns completely into saturated vapour. Assuming the saturated vapour to be an ideal gas find the increment of entropy and internal of the system.

Assuming the saturated water vapour to be ideal, find its pressure at the temperature 101.1 ^@C .

Unit mass of liquid of volume V_(1) completely turns into a gas of volume V_(2) at constant atmospheric pressure P and temperature T. The latent heat of vaporization is "L". Then the change in internal energy of the gas is

For water moI triangle _(vap) H = 41 kj mol^(-1) at 373 Kand 1 bar pressure. Assuming that water vapour is an ideal gas fhat occupies a much larger volume than liquid water, the internal energy change during evaporation of water is __________kJ mol^(-1) .

One mole of water being in equilibrium with a negligible amount of its saturated vapour at a temperature T_1 was completely converted into saturated vapour at a temperature T_2 . Find the entropy increment of the system. The vapour is assumed to be an ideal gas, the specific volume of the liquid is negligible on comparsion with that of the vapour.

A reversible isothermal evaporation of 90 g of water is carried out at 100^(@)C . Heat of evaporation of water is 9.72 kcal mol^(-1) . Assuming water vapour to behave like an ideal gas, what is the change in internal energy of the system ?

1 g of water, of volume 1 cm^3 at 100^@C , is converted into steam at same temperature under normal atmospheric pressure (= 1 xx 10^5 Pa) . The volume of steam formed equals 1671 cm^3 . If the specific latent heat of vaporisation of water is 2256 J/g, the change in internal energy is

A water vapour filling the space under the piston of a cylinder is compressed (or expanded) so that it remaind saturated all the time, being just on the verge of condensation. Find the molar heat capacity C of the vapour in this process as a function of temperature T , assuming the vapour to be an ideal gas and neglecting the specific volume of water in comparion with that of vapour. Calculate C at a temperature t = 100 ^@C .

1g of water at 100^(@)C is converted into steam at the same temperature. If the volume of steam is 1671 cm^(3) , find the change in the internal energy of the system. Latent of steam =2256 Jg^(-1) . Given 1 atmospheric pressure = 1.013xx10^(5) Nm^(-2)