Do water and ice have the same specific heats?

A small quantity mass m, of water at a temperature theta ("in " ^(@)C) is poured on to a larger mass M of ice which is at its melting point. If c is the specific heat capacity of water and L the specific heat capacity of water and L the specific latent heat of fusion of ice, then the mass of ice melted is give by

How much steam at 100^(@)C is needed to change 40 g of ice at -10^(@)C to water at 20^(@)C if the ice in a 50 g copper can? Assume that the can maintains the same temperature as the ice and water. Given that specific heat of copper is S_(Cu)=0.09 "cal"//gm^(@) and specific heat of ice is S_("ice")=0.5 cal /gm .^(@)C .

Find the final temeprature and composition of the mixture of 1 kg of ice at -10^(@)C and 4.4 kg of water at 30^(@)C . Given that specific heat of water is 4200J//kg^(@)C and that of ice is 2100J//kg^(@)C and latent heat of fusion of ice is 3.36xx10^(5) J/kg

The gases have two principal specific heats but solids and liquied have only one specific heat. Why ?

2kg of ice at 20^C@ is mixed with 5kg of water at 20^C@ in an insulating vessel having a negligible heat capacity. Calculate the final mass of water remaining in the container. It is given that the specific heats of water & ice are 1kcal//kg//^@C 0.5 kcal//kg//^@C while the latent heat of fusion of ice is 80kcal//kg

Ice in a freezer is at –7^(@)C . 100 g of this ice is mixed with 200 g of water at 15°C. Take the freezing temperature of water to be 0°C, the specific heat of ice equal to 2.2 J//g .^(@)C , specific heat of water equal to 4.2 J//g .^(@)C , and the latent heat of ice equal to 335 J/g. Assuming no loss of heat to the environment, the mass of ice in the final mixture is closest to

Ice at 20^(@)C is added to 50 g of water at 40^(@) . When the temperaurtre of the mixture reaches 0^(@)C , it is observed that 20 g of ice is still unmelted. The amount (in gram) of ice added to the water was (Specific heat of water =4.2J//g//""^(@)C Specific heat of ice =2.1J//g//""^(@)C Heat of fusion of water at 0^(@)C=334J//g)

10 gm of ice at -20^(@)C is dropped into a calorimeter containing 10 gm of water at 10^(@)C , the specific heat of water is twice that of ice. When equilibrium is reached the calorimeter will contain:

200 g of ice at –20°C is mixed with 500 g of water 20°C in an insulating vessel. Final mass of water in vessel is (specific heat of ice – 0.5 cal g^(–1°)C^(–1) )