A calorimeter of mass `0.2 kg` and specific heat `900 J//kg-K`. Containing `0.5 kg` of a liquid of specific heat `2400 J//kg-K`. Its temperature falls from `60^(@)C` to `55^(@)C` in one minute. Find the rate of cooling.

A heating coil is immersed in a calorimeter of heat capacity 50 J^@ C^(-1) containing 1.0 kg of a liquid of specific heat capacity 450 J kg^(-1) ""^@ C^(-1) . The temperature of liquid rises by 10^@ C when 2:0 A current is passed for 10 minutes. Find : (i) the resistance of the coil, (ii) the potential difference across the coil. State the assumption used in your calculations.

A metal piece of mass 20 g is heated to a constant temperature of 100^@ C. Then it is added in a calorimeter of mass 50 g and specific heat capacity 0.42 J g^(-1) K^(-1) , containing 50 g of water at 20^@ C. After stirring the water, the highest temperature recorded is 22^@ C. Calculate the specific heat capacity of metal. Specific heat capacity of water = 4.2 J g^(-1)K^(-1)

A calorimeter of heat capacity 100 J//K is at room temperature of 30^(@)C . 100g of water at 40^(@)C of specific heat 4200 J//kg-K is poured into the calorimeter. What is the temperature of water is calorimeter?

An unknown metal of mass 192 g heated to a temperature of 100^(@)C was immersed into a brass calorimeter of mass 128 g containing 240 g of water at a temperature of 8.4^(@)C . Calculate the specific heat of the unknown metal if water temperature stabilizes at 21.5^(@)C . (Specific heat of brass is 394 J kg^(-1) K^(-1) )

1300 J of heat energy is supplied to raise the temperature of 0.5 kg of lead from 20^@ C to 40^@ C. Calculate the specific heat capacity of lead.

A calorimeter contains 0.2 kg of water at 30^(@)C 0.1 kg of water at 60^(@)C is added to it, the mixture is well stirred and the resulting temperature is found to be 35^(@)C . The thermal capacity of the calorimeter is:

A calorimeter contains 0.2 kg of water at 30^@C . 0.1 kg of water at 60^@C is added to it, the mixture is well stirred and the resulting temperature if found to be 35^@C . The thermal capacity of the calorimeter is

Water of mass m_(2) = 1 kg is contained in a copper calorimeter of mass m_(1) = 1 kg . Their common temperature t = 10^(@)C . Now a piece of ice of mass m_(2) = 2 kg and temperature is -11^(@)C dropped into the calorimeter. Neglecting any heat loss, the final temperature of system is. [specific heat of copper =0.1 Kcal//kg^(@)C , specific heat of water = 1 Kcal//kg^(@)C , specific heat of ice = 0.5 Kcal//kg^(@)C , latent heat of fusion of ice = 78.7 Kcal//kg ]

A 0.60 kg sample of water and a sample of ice are placed in two compartmetnts A and B separated by a conducting wall, in a thermally insulated container. The rate of heat transfer from the water to the ice through the conducting wall is constant P, until thermal equilibrium is reached. The temperature T of the liquid water and the ice are given in graph as functions of time t. Temperature of the compartments remain homogeneous during whole heat transfer process. Given specific heat of ice =2100 J//kg-K , specific heat of water =4200 J//kg-K , and latent heat of fusion of ice =3.3xx10^5 J//kg . Initial mass of the ice in the container equal to

A 0.60 kg sample of water and a sample of ice are placed in two compartmetnts A and B separated by a conducting wall, in a thermally insulated container. The rate of heat transfer from the water to the ice through the conducting wall is constant P, until thermal equilibrium is reached. The temperature T of the liquid water and the ice are given in graph as functions of time t. Temperature of the compartments remain homogeneous during whole heat transfer process. Given specific heat of ice =2100 J//kg-K , specific heat of water =4200 J//kg-K , and latent heat of fusion of ice =3.3xx10^5 J//kg . Initial mass of the ice in the container equal to