A calorimeter contains 500gm of water and 300gm of ice, all at a temperature of 0...

Answer the following questions: a) A calorimeter, specific heat capacity 500.0 J/kgC, mass 200.0 g, contains...

Answer the following questions: a) A calorimeter, specific heat capacity 500.0 J/kgC, mass 200.0 g, contains 300.0 g of water at 40.0 C. If 50.0 g of ice at 0.00 C is dropped into the water and stirred, the temperature of the mixture when the ice has melted is 23.8 C. Calculate the heat of fusion of ice. b) What is the final temperature attained when 900.0 g of ice at 0.00 C is dropped into 3400.0 g of water...

A calorimeter contains 75.0 g of water at an initial temperature of 25.2 °C. 151.28 g...

A calorimeter contains 75.0 g of water at an initial temperature of 25.2 °C. 151.28 g of copper metal at a temperature of 95.5 °C was placed in the calorimeter. The equilibrium temperature was 36.2 °C. The molar heat capacity of water is 75.4 J / mol °C. Determine the molar heat capacity of the copper.

An insulated aluminum calorimeter vessel of 150 g mass contains 300 g of liquid nitrogen boiling...

An insulated aluminum calorimeter vessel of 150 g mass contains 300 g of liquid nitrogen boiling at 77 K. A metal block at an initial temperature of 303 K is dropped into the liquid nitrogen. It boils away 15.8 g of nitrogen in reaching thermal equilibrium. The block is then withdrawn from the nitrogen and quickly transferred to a second insulated copper calorimeter vessel of 200 g mass containing 500 g of water at 30.1 degrees celsius. The block coolds...

An ideal calorimeter is adibiatic, and does not absorb heat from the system it contains. Such...

An ideal calorimeter is adibiatic, and does not absorb heat from the system it contains. Such a calorimeter contains 250 mL of water at 85°C. To this, a block of ice weighing 25g at -10°C is added. What is the final temperature of the system? Write the appropriate thermodynamic cycle. Assume literature values for all heat capacities, independent of temperature. Values of melting point, ΔHfus, etc. can be taken from literature.

A coffee-cup calorimeter contains 130.0 g of water at 25.3 ∘C . A 124.0-g block of...

A coffee-cup calorimeter contains 130.0 g of water at 25.3 ∘C . A 124.0-g block of copper metal is heated to 100.4 ∘C by putting it in a beaker of boiling water. The specific heat of Cu(s) is 0.385 J/g⋅K . The Cu is added to the calorimeter, and after a time the contents of the cup reach a constant temperature of 30.3 ∘C . Part A Determine the amount of heat, in J , lost by the copper block....

A calorimeter contains 82.4 grams of water at 20.9 °C. A 156 -gram piece of an...

A calorimeter contains 82.4 grams of water at 20.9 °C. A 156 -gram piece of an unknown metal is heated to 81.9 °C and dropped into the water. The entire system eventually reaches 26.6 °C. Assuming all of the energy gained by the water comes from the cooling of the metal—no energy loss to the calorimeter or the surroundings—calculate the specific heat of the metal. The specific heat of water is 4.18 J/g · °C _____J/g · °C

The heat gained by the ice melted the ice and raised the temperature of the melted...

The heat gained by the ice melted the ice and raised the temperature of the melted ice from its initial temperature to the final temperature of the water in the calorimeter. Use this information to calculate the heat of fusion per gram of ice for each trial. Enter your values using the correct number of significant figures. This may be 2 or 3 digits. heat capacity of calorimeter =56.4 J/C q(calorimeter)+q(water) = -( q(ice)+q(ice water) ) Trial # qwater qcalorimeter...

In an experiment to determine the enthalpy of fusion of ice, the following data was collected:...

In an experiment to determine the enthalpy of fusion of ice, the following data was collected: Initial mass of water in the calorimeter = 70.89g Initial temperature of the water in the calorimeter = 17.6 degrees C Final mass of temperature in the calorimeter = 0.0 degrees C Please calculate: a) the mass of the ice that melted b) the number of mol of ice that melted c) the change in temperature of the initial mass of water in the...

A copper calorimeter can with mass 0.860 kg contains 0.185 kg of water and 0.020 kg...

A copper calorimeter can with mass 0.860 kg contains 0.185 kg of water and 0.020 kg of ice in thermal equilibrium at atmospheric pressure. Part A: What is the temperature of the ice–water mixture? Part B: If 0.775 kg of lead at a temperature of 255 ∘C is dropped into the can, what is the final temperature of the system? (Assume no heat is lost to the surroundings.)

An 100-g aluminum calorimeter contains 280 g of water at an equilibrium temperature of 20°C. A...

An 100-g aluminum calorimeter contains 280 g of water at an equilibrium temperature of 20°C. A 170-g piece of metal, initially at 277°C, is added to the calorimeter. The final temperature at equilibrium is 32°C. Assume there is no external heat exchange. The specific heats of aluminum and water are 910 J/kg·K and 4190 J/kg·K, respectively. The specific heat of the metal is closest to: a) 270 J/kg·K. b) 240 J/kg·K. c) 330 J/kg·K. d) 390 J/kg·K. e) 360 J/kg·K.