What mass of water at 23.0 °C must be allowed to come to thermal equilibrium with...

What mass of water at 23.0°C must be allowed to come to thermal equilibrium with a...

What mass of water at 23.0°C must be allowed to come to thermal equilibrium with a 1.80-kg cube of aluminum initially at 150°C to lower the temperature of the aluminum to 61.0°C? Assume any water turned to steam subsequently recondenses. Your response is off by a multiple of ten. kg My answer was 906.40 kg and I got it wrong

What mass of water at 25.0°C must be allowed to come to thermal equilibrium with a...

What mass of water at 25.0°C must be allowed to come to thermal equilibrium with a 1.85kg cube of aluminum initially at 1.50 x 102 °C to lower the temperature of the aluminum to 65.0°C? Assume any water turned to steam subsequently recondenses.

A sample of copper with a mass of 1.80 kg, initially at a temperature of 150.0°C,...

A sample of copper with a mass of 1.80 kg, initially at a temperature of 150.0°C, is in a well-insulated container. Water at a temperature of 27.0°C is added to the container, and the entire interior of the container is allowed to come to thermal equilibrium, where it reaches a final temperature of 70.0°C. What mass of water (in kg) was added? Assume any water turned to steam subsequently recondenses.

A block of tin with a mass of 1.70 kg, initially at a temperature of 150.0°C,...

A block of tin with a mass of 1.70 kg, initially at a temperature of 150.0°C, is in a well-insulated container. Water at a temperature of 26.0°C is added to the container, and the entire interior of the container is allowed to come to thermal equilibrium, where it reaches a final temperature of 61.0°C. What mass of water (in kg) was added? Assume any water turned to steam subsequently recondenses.

An aluminum cup of mass 110 g contains 800 g of water in thermal equilibrium at...

An aluminum cup of mass 110 g contains 800 g of water in thermal equilibrium at 80.0°C. The combination of cup and water is cooled uniformly so that the temperature decreases by 1.50°C per minute. At what rate is energy being removed by heat? Express your answer in watts. W

A 23.0 g copper ring at 0.000°C has an inner diameter of D = 2.46000 cm....

A 23.0 g copper ring at 0.000°C has an inner diameter of D = 2.46000 cm. An aluminum sphere at 100.0°C has a diameter of d = 2.46507 cm. The sphere is put on top of the ring, and the two are allowed to come to thermal equilibrium, with no heat lost to the surroundings. The sphere just passes through the ring at equilibrium temperature. What is the mass of the sphere?

A 23.0 g copper ring at 0.000°C has an inner diameter of D = 2.46000 cm....

A 23.0 g copper ring at 0.000°C has an inner diameter of D = 2.46000 cm. An aluminum sphere at 100.0°C has a diameter of d = 2.46507 cm. The sphere is put on top of the ring, and the two are allowed to come to thermal equilibrium, with no heat lost to the surroundings. The sphere just passes through the ring at equilibrium temperature. What is the mass of the sphere?

A 23.0 g copper ring at 0.000°C has an inner diameter of D = 2.46000 cm....

A 23.0 g copper ring at 0.000°C has an inner diameter of D = 2.46000 cm. An aluminum sphere at 100.0°C has a diameter of d = 2.46507 cm. The sphere is put on top of the ring, and the two are allowed to come to thermal equilibrium, with no heat lost to the surroundings. The sphere just passes through the ring at equilibrium temperature. What is the mass of the sphere?

I place an ice cube with a mass of 0.223 kg and a temperature of −35°C...

I place an ice cube with a mass of 0.223 kg and a temperature of −35°C is placed into an insulated aluminum container with a mass of 0.553 kg containing 0.452 kg of water. The water and the container are initially in thermal equilibrium at a temperature of 27°C. Assuming that no heat enters or leaves the system, what will the final temperature of the system be when it reaches equilibrium, and how much ice will be in the container...

A 27.0 −g aluminum block is warmed to 65.6 ∘C and plunged into an insulated beaker...

A 27.0 −g aluminum block is warmed to 65.6 ∘C and plunged into an insulated beaker containing 55.1 g water initially at 22.4 ∘C. The aluminum and the water are allowed to come to thermal equilibrium. Assuming that no heat is lost, what is the final temperature of the water and aluminum?