Cooling Lead Shot: Final Temp Calculation

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To find the final temperature of a mixture of lead shot and water, the heat lost by the lead must equal the heat gained by the water. The specific heat capacities of lead and water are given as 128 J/(kg·°C) and 4187 J/(kg·°C), respectively. The equation Q = mcΔT is used for both substances, where the mass is 5 kg for each. The energy transfer is set up as the heat lost by the lead equaling the heat gained by the water, leading to the equation (5 kg)(128 J/kg·°C)(97.9 - Tf) = (5 kg)(4187 J/kg·°C)(Tf - 26). Solving this equation will yield the final temperature of the mixture.
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Homework Statement


5 kg of lead shot at 97.9 °C are poured into 5 kg of water at 26.0 °C. Find the final temperature of the mixture. Use cwater = 4187 [(J)/(kg·° C)] and clead = 128 [(J)/(kg·° C)].


Homework Equations





The Attempt at a Solution


How do I start this?
 
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There are the initial energy content of the water and of the lead shot.

The energy must transfer from hot (lead) to cold (water), i.e. the difference (change) in energy content of the lead, which is related to the temperature change, must equal the change in energy of the water.

And ultimately, they have the same temperature.
 
So can I use Q = mc * change in temperature?
 
BuBbLeS01 said:
So can I use Q = mc * change in temperature?

Yes - realizing that the lead and water will have the same, as yet to be determined, temperature T.
 
Q = (Ml * Cl * CH T) + (Mw * Cw * CH T)
Q = CH T * [(Ml * Cl) + (Mw * Cw)]
Q = CH T (21575)
Q = Tf - Ti * (21575)
Tf = (97.9C + 273K) * (21575) = 8002167.5
Was I supposed to subtract the lead and water? Cause that's obviously wrong hehe.
 
Why am I getting such a huge number?
 
Does anyone know how to do this?
 
The lead starts at some temperature Th and cools to temperature T, which one is trying to find, so the temperature change (Th - T) is proportional to thermal energy lost. At the same time, the water is starting at some temperature Tc and heats to temperature T, and the change (T - Tc) is proportional to the heat gained, and that heat (thermal energy) comes from the lead.

Assuming not heat is lost from the system |\Delta{Q}_{Pb}| = |\Delta{Q}_{water}|

and \Delta{Q} = mc_p\Delta{T}
 
Okay so my m is just the mass of the lead?
Change in Q = (5kg) * (128J/kg*C) * Change in T (97.9 - T)
 
  • #10
BuBbLeS01 said:
Okay so my m is just the mass of the lead?
Change in Q = (5kg) * (128J/kg*C) * Change in T (97.9 - T)
That is fine for the lead.

Now do the same for the water.
 
  • #11
Change in Qpb = (5kg) * (128J/kg*C) * Change in T (97.9 - T)
Change in Qw = (5kg) * (4187J/kg*C) * Change in T (26 - T)
 
  • #12
so I set them equal to each other
 

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