The specific heat of ice at `0^(@)C` is

19 g of water at 30^@C and 5 g of ice at -20^@C are mixed together in a calorimeter. What is the final temperature of the mixture? Given specific heat of ice =0.5calg^(-1) (.^(@)C)^(-1) and latent heat of fusion of ice =80calg^(-1)

Specific heat of water at 20^@C is _______ and that of ice is _________

Ten grams of ice at - 20^(@)C is to be changed to steam at 130^(@)C . The specific heat of both ice and steam is 0.5 cal // ( g^(@)C) . The specific heat of water is 1.00 cal // ( g K ) . The heat of fusion is 80 cal // g and the heat of vaporization is 540 cal // g. The entire process requires.

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

In summer, Kamal decides to take a bath at noon. Temperature of the water in overhead tank is 45^(@)C so he decides to mix ince from refrigerator. The temperature of the ice in refrigerator. The temperature of the ice in refrigerator is 10^(@)C . How much ice will be needed to prepare 20 kg of water at 25^(@)C for bath? (Assume no loss to surrounding latent heat of fusion of ice =80cal//gm , specific heat of ice =0.5cal//gm^(@)C

How many grams of ice at -14 .^(@)C are needed to cool 200 gram of water form 25 .^(@)C to 10 .^(@)C ? Take specific heat of ice =0.5 cal g^(-1) .^(@)C^(-1) and latant heat of ice = 80 cal g^(-1) .

Calculate the amount of heat that must be absorbed by 5g of ice at 120^(@)C to convert it to water at 2^(@)C . Use the specfic heat of ice (2.09 Jg^(-1) 1^(@)C^(-1)) , enthalpy of fusion of ice (334 J g^(-1)) , and specific heat of water (4.18 J g^(-1) .^(@)C^(-1)) for calculation Strategu : We must calculate the amount of heat absorbed during three steps. ltbrrgt (i) Wariming 50 g of ice from -12^(@)C to its melting point 0^(@)C . This requires the specific heat of ice. Melting the ice with no change in temperature . This needs the entholpy of fusion of ice at 0^(@)C . Warming the resulting liquid from 0^(@)C to 20^(@)C . This requires specific heat of water underset("Ice at" - 12^(@)C)(50 g) overset(Step 1)rarr underset("Ice at" 0^(@)C)(50 g) overset(Setp 2)rarr underset("Water at" 0^(@)C)(50g) overset(Setp 3)rarr underset("Water at" 20^(@)C)(50 g)

A metal piece weighing 15 g is heated to 100^(@)C and then immersed in a mixture of ice and water at the thermal equilibrium. The volume of the mixture is found to be reduced by 0.15 cm^(3) with the temperature of mixture remaining constant. Find the specific heat of the metal. Given specific gravity of ice = 0.92 , specific gravity of water at 0^(@)C = 1.0 , latent heat of fusion of ice = 80 cal-g^(-1) .

suppose you want to cool 0.25 kg of cola (mostly water ), at 25^(@)C by adding ice initially at -20^(@)C . How much ice should you add so that the final temperature will be 0^(@)C with all the ice melt? Neglect the heat capacity of the container. specific heat of ice is 2000 Jkg^(-1)K^(-1) . [take specific heat of cola 4160 Jkg^(-1)K^(-1) .]