`1 g` steam at `100^@C` is passed in an insulating vessel having `1 g` ice at `0^@C`. Find the equilibrium composition of the mixture. (Neglecting heat capacity of the vessel).

50 g ice at 0^(@)C in kept in an insulating vessel and 50 g water at 100^(@)C is mixed in it. Then the final temperature of the mixture is (neglect the heat loss)

1 g ice at 0^@C is placed in a calorimeter having 1 g water at 40^@C . Find equilibrium temperature and final contents. Assuming heat capacity of calorimeter is negligible small.

1 g ice at -40^@C . Is placed in a container having 1 g water at 1^@C . Find equilibrium temperature. Assume heat capacity of container is negligibly small.

2g ice at 0^(@)C is mixed with 1 g steam at 100^(@)C . Find the final temperature of the mixture.

5 g ice at 0"^(C) is mixed with 1 g steam at 100"^(C ) .Find the final temperture and compostion of the mixture.

1 g of ice at 0^@C is mixed with 1 g of steam at 100^@C . After thermal equilibrium is achieved, the temperature of the mixture is

A vessel containing 100 g ice at 0^(@)C is suspended in a room where temperature is 35^(@)C . It was found that the entire ice melted in 10 hour. Now the same vessel containing 100 g of water at 0^(@)C is suspended in the same room. How much time will it take for the temperature of water to rise to 0.5^(@)C . Neglect the heat capacity of the vessel. Specific heat of water and specific latent heat of fusion of ice are 1 cal g^(-1) .^(@)C^(-1) and 80 cal g^(-1) respectively.

100 g ice at 0^(@)C is mixed with 10 g steam at 100^(@)C . Find the final temperature and composition .

30 kg ice at 0^@C and 20 g of steam at 100^@C are mixed. The composition of the resultant mixture is

30 g ice at 0”^(@)C is mixed with 25 g steam at 100”^(@)C . Find the final temperature and composition