A 100.0g sample of water at 90 degree C is added to a 500.0g sample of...

100 g of solid ice at 0 degree Celcius is added to 500 g of liquid...

100 g of solid ice at 0 degree Celcius is added to 500 g of liquid water at 90 degree celcius. What is the final temperature? What initial water temperature is required so that 10 g of ice remain once equilibrium has been reached?

1.) How much cold water at 4.26 degree C must be added to 667 g of...

1.) How much cold water at 4.26 degree C must be added to 667 g of water at 45 degree C such that the final temperature of the mixture is 25.0 degree C? No heat is exchanged with the surroundings. Express your answer in grams. 2.) Calculate the amount of heat, in kJ, required to turn 511 g of ice at -15.30C into water at 250C.

A 42.14−g sample of water at 87.8°C is added to a sample of water at 25.4°C...

A 42.14−g sample of water at 87.8°C is added to a sample of water at 25.4°C in a constant-pressure calorimeter. If the final temperature of the combined water is 40.1°C and the heat capacity of the calorimeter is 26.3 J/°C, calculate the mass of the water originally in the calorimeter. Enter your answer in scientific notation.

Two samples of copper metal (20.0g and 100.0g) are heated using boliing water (T=100C). The 20.0g...

Two samples of copper metal (20.0g and 100.0g) are heated using boliing water (T=100C). The 20.0g sample is heated for 120 minutes white the 100.0g sample is heated for 60 minutes. Assuming it takes only 30 minutes for the metals to reach thermal equilibrium with the water regardless of the amount of metal, what can be said about the final temperature and energy content (the heat) of the metal samples?

In an insulated container, a 5.0 g sample of water at 80.°C was added to an...

In an insulated container, a 5.0 g sample of water at 80.°C was added to an unknown mass of cooler water at 30.°C. The final temperature of the resulting mixture became 35°C. What mass of cooler water was present? (Assume the container itself adsorbed a negligible amount of heat.)

A 771-g aluminum pot contains 520 g of water. Their temperature is 93.5 degree C. 260...

A 771-g aluminum pot contains 520 g of water. Their temperature is 93.5 degree C. 260 g of water at 1.87 degree C are added to the pot. Calculate the final temperature of the water and the aluminum after they reach thermal equilibrium. Assume no heat is exchanged with the surroundings. Express your answer in degree C.

Determine the minimum mass (in g) of NaCl (assume ideal behavior/values) required to keep 100.0g of...

Determine the minimum mass (in g) of NaCl (assume ideal behavior/values) required to keep 100.0g of water from freezing at a temperature of -15.0 degree Celsius. The Kb of water is 0.512 degree Celsius/m and the Kf of water is 1.86 degree Celsius/m.

2.50 kg of water at 90 (degrees of C) is contained in a thermally-isolated container. A...

2.50 kg of water at 90 (degrees of C) is contained in a thermally-isolated container. A 1.50 kg chunk of ice at - 10 degrees C is added to the water, in the same thermally isolated container. a.) Describe the final state of the system when it has reached thermal equilibrium, give the final temperature and the amount of ice let (if any). b.) Find the net change in entropy of the system during this process.

A 102.5 g sample of metal beads was heated in a water bath to 99.5deg. Celsius....

A 102.5 g sample of metal beads was heated in a water bath to 99.5deg. Celsius. The metal was then added to a sample of water (25.7g) and the temperature of the water changed from an initial temperature of 20.0 deg. Celsius to a final temperature of 41.5 degree Celsius. A) What was the temperature of the metal at equilibrium? B) What was the temperature change of the metal? C) Calculate the specific heat and the atomic mass of the...

A 31 g block of ice is cooled to −90◦C. It is added to 591 g...

A 31 g block of ice is cooled to −90◦C. It is added to 591 g of water in an 65 g copper calorimeter at a temperature of 26◦C. Find the final temperature. The specific heat of copper is 387 J/kg · ◦C and of ice is 2090 J/kg · ◦C . The latent heat of fusion of water is 3.33 × 105 J/kg and its specific heat is 4186 J/kg · ◦C . Answer in units of ◦C.