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 vaporazisation 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 0^(@)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) .

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) .

If x gm of steam at 100^(@) C is mixed with 5x gm of ice at 0^(@)C , calculate the final temperature of resultiong mixture. The heat of vapourisation and fusion are 540 cal gm^(-1) and 80 cal gm^(-1) respectively.

Steam at 100^(@)C is passed into 20 g of water at 10^(@)C when water acquire a temperature of 80^(@)C , the mass of water present will be [Take specific heat of water = 1 cal g^(-1).^(@) C^(-1) and latent heat of steam = 540 cal g^(-1) ]

Stream at 100^(@)C is passed into 20 g of water at 10^(@)C . When water acquires a temperature of 80^(@)C , the mass of water present will be [Take specific heat of water =1 cal g^(-1) .^(@)C^(-1) and latent heat of steam =540 cal g^(-1) ]

A cube of ice of mass 30 g at 0^@ C is added into 200 g of water at 30^@ C. Calculate the final temperature of water when whole of the ice cube has melted. Given: specific latent heat of ice = 80 cal g^(-1) , specific heat capacity of water = 1 cal g^(-1)^@C^(-1)

If the boiling point of an aqueous solution containing a non-volatile solute is 100.1^(@)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.

When m gram of steam at 100^(@) C is mixed with 200 gm of ice at 0^(@)C . it results in water at 40^(@) C . Find the value of m in gram . (given : Latent heat of fusion ( L_f ) = 80 cal/gm, Latent heat of vaporisation ( L_v ) = 540 cal/gm., specific heat of water ( C_w )= 1 cal/gm/C)

When m gram of steam at 100^@ C is mixed with 200 gm of ice at 0^@ C. it results in water at 40^@ C . Find the value of m in gram . (given : Latent heat of fusion ( L_f ) = 80 cal/gm, Latent heat of vaporisation ( L_v ) = 540 cal/gm., specific heat of water ( C_w )= 1 cal/gm/C)

A mole of steam is condensed at 100^(@) C, the water is cooled to 0^(@) C and frozen to ice . What is the difference in entropies of the steam and ice? The heat of vaporization and fusion are 540 cal" "gm^(-1) and 80 cal" "gm ^(-1) respectively . Use the average heat capacity of liquild water as 1 cal" "gm^(-1) degree^(-1) . a. Entropy change during the condensation of steam is -26.06 cal//^(@)C b. Entropy change during cooling of water from 100^(@)C "to" 0^(@)C "is" - 5.62 cal//^(@)C c. Entropy change during freezing of water at 0^(@)C "is" -5.27 cal//^(@)C d. Total entropy changwe is -36.95 cal//^(@)C