If boiling point of an aqueous solution is `100.1^(@)C`. What is its freezing point? Given latent heat of fusion and vaporization of water are `80calg^(-1)` and `540 calg^(-1)` respectively.

If the boiling point of an aqueous solution containing a non-volatile solute is 100.15^(@)C . What is its freezing point? Given latent heat of fusion and vapourization of water 80 cal g^(-1) and 540 cal g^(-1) , respectively.

If the boiling point of an aqueous solution is 100.1^(@)C , what is its freezing point ? Given l_(f)=80 , l_(v)=540 "cal" g^(-1) respectively, of H_(2)O .

Calculate the amount of heat required in calorie to change 1 g of ice at -10^(@)C to steam at 120^(@)C . The entire process is carried out at atmospheric pressure. Specific heat of ice and water are 0.5 cal g^(-1) .^(@)C^(-1) and 1.0 cal g^(-1) .^(@)C^(-1) respectively. Latent heat of fusion of ice and vaporization of water are 80 cal g^(-1) and 540 cal g^(-1) respectively. Assume steam to be an ideal gas with its molecules having 6 degrees of freedom. Gas constant R = 2 cal mol^(-1) K^(-1) .

Steam at 100°C is passed into 100 g of ice at 0°C . Finally when 80g ice melts the mass of water present will be [Latent heat of fusion and vaporization are 80 cal g^(-1) and 540 cal g^(-1) respectively, specific heat of water = 1 cal g^(-1) °C^(-1) ]

How much heat is required to change 10g ice at 10^(@)C to steam at 100^(@)C ? Latent heat of fusion and vaporisation for H_(2)O are 80 cl g^(-1) and 540 cal g^(-1) , respectively. Specific heat of water is 1cal g^(-1) .

One mole of ice is melted at 0^(@)C and then is heated to 100^(@)C . What is the difference in entropies of the steam and ice? The heats of vaporisation and fusion are 540 cal g^(-1) and 80 cal g^(-1) respectively. Use the average heat capacity of liquid water as 1cal g^(-1) degree^(-1)