Specific heat capacity of a solid material

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Homework Help Overview

The discussion revolves around calculating the specific heat capacity of a solid material given its mass, temperature change, energy input, and efficiency of the heating process. The problem is situated within the context of thermodynamics and energy transfer.

Discussion Character

  • Exploratory, Assumption checking, Conceptual clarification

Approaches and Questions Raised

  • Participants discuss the correct application of the efficiency factor in the calculation of specific heat capacity. There are questions about how to adjust the energy input based on the efficiency provided.

Discussion Status

Participants are exploring the implications of efficiency on the calculation. Some have confirmed the methodology while others are clarifying the correct percentage to apply. There is acknowledgment of a similar problem in another thread, indicating a broader context of inquiry.

Contextual Notes

There is mention of a lack of instruction regarding efficiency in the original poster's coursework, which may affect their understanding of the problem. Additionally, there are references to potential discrepancies in software responses to submitted answers.

Aleisha
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Homework Statement


A 4.80 kg piece of solid material is heated from 16.4C to 219C (3 s.f.) using 787 kJ of energy (3 s.f.).

Assuming an efficiency of 0.383 for the heating process, and that the material does not melt, calculate the specific heat capacity of the material.

Homework Equations


Q=mc(Change in T)

The Attempt at a Solution


c=Q/ m (Delta T)
=(787e3)/ (4.80 x 202.6)
= 809.2711418 k/kg/K
However they have given me a efficiency of 0.383? Do i just time that by my answer? We haven't been taught about efficiency.

Thank you
 
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Aleisha said:
We haven't been taught about efficiency.
If you use 1kJ of energy in a heating process, but the process is only 30% efficient, how much heat ends up where it is wanted? (Not something that really requires teaching, I'd say.)
 
Your methodology is correct as is your answer if all of the heat energy goes into heating the body. If however, only 38.37% of the heat energy supplied goes into heating the body, you need to make an adjustment in your calculation.
 
haruspex said:
If you use 1kJ of energy in a heating process, but the process is only 30% efficient, how much heat ends up where it is wanted? (Not something that really requires teaching, I'd say.)
So my answer will be approximately 30% of 809.27k/kg/K?
 
Dr Dr news said:
Your methodology is correct as is your answer if all of the heat energy goes into heating the body. If however, only 38.37% of the heat energy supplied goes into heating the body, you need to make an adjustment in your calculation.
Thank you very much! So I should just find 38.3% of my answer (809.27)? Is that correct because it’s only being 30% efficient in its absorbance?
 
Aleisha said:
So my answer will be approximately 30% of 809.27k/kg/K?
That's the approach, but not 30%. That was a number I made up to illustrate. Use the given 0.383, i.e. 38.3%.
 
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haruspex said:
That's the approach, but not 30%. That was a number I made up to illustrate. Use the given 0.383, i.e. 38.3%.
Yes that’s understandable thank you :)
 
Aleisha said:
Yes that’s understandable thank you :)
There's another thread currently that looks the exact same problem, just slightly different numbers. I guess this is software generated. We can't find an error in the student's work (unless wrong numbers were posted in the thread), but the software is rejecting the answer.
I'd be interested to know whether you have better luck.
 
haruspex said:
There's another thread currently that looks the exact same problem, just slightly different numbers. I guess this is software generated. We can't find an error in the student's work (unless wrong numbers were posted in the thread), but the software is rejecting the answer.
I'd be interested to know whether you have better luck.
I got an overall answer of 310 J/kg/K and the answer was correct. All the data was copy and pasted from my question. Thank you for your help :)
 
  • #10
Aleisha said:
I got an overall answer of 310 J/kg/K and the answer was correct. All the data was copy and pasted from my question. Thank you for your help :)
OK, thanks
 

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