As shown in the figure below, you have a system including a Cadmium vessel with mass...

Finding the equilibrium temperature of a mixture: An isolated thermal system consists of a copper container...

Finding the equilibrium temperature of a mixture: An isolated thermal system consists of a copper container filled with a quantity of liquid water and a quantity of ice. What is the fully thermalized state of the system (the final temperature, how much water, and how much ice) provided that initially there is 1.0 kg of ice at -100 degrees Celsius, 10 kg of water at 1 degrees Celsius, and the copper container has the mass of 15.0 kg and is...

A copper pot with a mass of 0.500 kg contains 0.175 kg of water, and both...

A copper pot with a mass of 0.500 kg contains 0.175 kg of water, and both are at a temperature of 23.0 ∘C. A 0.240 kg block of iron at 85.5 ∘C is dropped into the pot. Find the final temperature of the system, assuming no heat loss to the surroundings. Express your answer in degrees Celsius.

A copper pot with a mass of 0.500 kg contains 0.195 kg of water, and both...

A copper pot with a mass of 0.500 kg contains 0.195 kg of water, and both are at a temperature of 22.5 ∘C. A 0.245 kg block of iron at 85.0 ∘C is dropped into the pot. Find the final temperature of the system, assuming no heat loss to the surroundings. Express your answer in degrees Celsius.

You have 1.30 kg of water at 27.6 Degree Celsius in an insulated container of negligible...

You have 1.30 kg of water at 27.6 Degree Celsius in an insulated container of negligible mass. You add 0.580 kg of ice that is initially at -21.0 Degree Celsius. Assume no heat is lost to the surroundings and the mixture eventually reaches thermal equilibrium. If all of the ice has melted, What is the final temperature (in Degree Celsius, round to 2 decimal places) of the water in the container? Otherwise if some ice remains, what is the mass...

You have a pitcher with 2.00 L of water at an initial temperature of 12.0 oC...

You have a pitcher with 2.00 L of water at an initial temperature of 12.0 oC and you wish to add ice to it to bring the temperature down. If the ice starts at an initial temperature of T1 = -18.4 oC, calculate the mass of ice required to reach a final state of all liquid water at 0.00 oC. *****Assume no heat is gained or lost to the surroundings.***** More information: Melting point of water - 0.00 degrees celcius...

You have 1.60 kg of water at 27.0°C in an insulated container of negligible mass. You...

You have 1.60 kg of water at 27.0°C in an insulated container of negligible mass. You add 0.640 kg of ice that is initially at -22.6°C. Assume no heat is lost to the surroundings and the mixture eventually reaches thermal equilibrium. If all of the ice has melted, what is the final temperature (in °C, round to 2 decimal places) of the water in the container? Otherwise if some ice remains, what is the mass of ice (in kg, round...

You have 1.45 kg of water at 27.4°C in an insulated container of negligible mass. You...

You have 1.45 kg of water at 27.4°C in an insulated container of negligible mass. You add 0.680 kg of ice that is initially at -22.4°C. Assume no heat is lost to the surroundings and the mixture eventually reaches thermal equilibrium. If all of the ice has melted, what is the final temperature (in °C, round to 2 decimal places) of the water in the container? Otherwise if some ice remains, what is the mass of ice (in kg, round...

21) A person carries a 25.0-N rock through the path shown in the figure, starting at...

21) A person carries a 25.0-N rock through the path shown in the figure, starting at point A and ending at point B. The total time from A to B is 1.50 min. How much work did gravity do on the rock between A and B? A) 625 J B) 20.0 J C) 275 J D) 75 J E) 0 J 22) A person carries a 2.00-N pebble through the path shown in the figure, starting at point A and...