Heat gained and lost by aluminium and water in thermal equilibrium

AI Thread Summary
The discussion revolves around a physics problem involving heat transfer between water and an aluminum cup. The final equilibrium temperature of the system is determined to be 71.847°C. The calculations for heat lost by the hot water and heat gained by the cold water are confirmed to be correct, with values of -11784.8 J and 10851.57 J, respectively. For the aluminum cup, it is clarified that assuming it starts at the same temperature as the water inside is valid for solving the problem. Overall, the approach to the calculations is validated, and the methodology for finding the heat gained by the aluminum is acknowledged as appropriate.
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Homework Statement


A physicist pours 100g of water at 100'C into a 20g aluminium cup which already contains 50g of water at 20'C. The final equilibrium temperature of the water is 71.847.
C(water)=4186J/kgC
C(aluminium)=900J/kgC

1. the amount of heat lost by the hot water
2. the amount of heat gained by the aluminium
3. the amount of heat gained by the cold water


Homework Equations


Q=mc(dt)

The Attempt at a Solution



I have attempted to answer them but really have no clue if the answers I am getting are right or if I am even using the correct approach because we weren't given answers or solutions

1: Q=(100e-3)(4186)(71.847-100)=-11784.8
2. I am really unsure about how to do this. Is it relevant that we don't know the initial temperature of the aluminium or can we assume it is in equilibrium with the water inside?
3. Q=(50e-3)(4186)((71.847-20)= 10851.57

Any help would be great, and/or if you wouldn't mind checking my answers. Thanks :)
 
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yep, looks good. I get the same answers as you do. And for question 2), you have the right idea. You assume that the aluminium is initially in equilibrium with the water inside. So you've got the initial temperature, and using a similar reasoning can give you the final temperature.
 

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