Specific Heat Capacity & Temperature

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SUMMARY

The discussion centers on the relationship between specific heat capacity and temperature, emphasizing that temperature is defined as the average molecular kinetic energy. It is established that a material's specific heat capacity is influenced by how energy is distributed between kinetic energy and other forms of energy, such as vibrational and rotational energy. Different substances exhibit varying specific heat capacities due to their molecular structures and the energy storage mechanisms involved. The Boltzmann equation is referenced to clarify that only translational vibrations contribute to temperature, while other internal modes also absorb energy.

PREREQUISITES
  • Understanding of basic thermodynamics concepts
  • Familiarity with molecular kinetic energy and its relation to temperature
  • Knowledge of vibrational and rotational energy modes in molecules
  • Basic grasp of the Boltzmann equation
NEXT STEPS
  • Research the Boltzmann equation and its implications for temperature and energy distribution
  • Explore the differences in specific heat capacities among various materials
  • Study the role of molecular structure in energy absorption and storage
  • Investigate the relationship between temperature and different forms of molecular motion
USEFUL FOR

Students and professionals in physics, materials science, and engineering who seek to deepen their understanding of thermodynamic principles and specific heat capacity variations among substances.

Christopher M
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This is not a homework question, just a question about physics that seems too basic to post in the main physics discussion forum. Please let me know if it is misplaced.

Temperature is average molecular kinetic energy. Is it therefore correct to say that a material's specific heat capacity depends entirely on the following question: when you put energy into the material, how does it divide that energy up between, on the one hand, kinetic energy of molecules, and on the other hand, other forms of energy?

In other words, is the reason that different substances have different specific heat capacities simply that some substances, when they take in energy, store it in forms other than molecular kinetic energy?

Thanks.
 
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Welcome to PF!

Christopher M said:
Temperature is average molecular kinetic energy. Is it therefore correct to say that a material's specific heat capacity depends entirely on the following question: when you put energy into the material, how does it divide that energy up between, on the one hand, kinetic energy of molecules, and on the other hand, other forms of energy?

In other words, is the reason that different substances have different specific heat capacities simply that some substances, when they take in energy, store it in forms other than molecular kinetic energy?

Hi Christopher! Welcome to PF! :smile:

If we're talking about a solid, I've always assumed that the different specific heat capacities are because the molecules vibrate back and forth differently because they're more or less strongly bound.

I don't see what other forms (than kinetic energy) the energy could go into. :confused:
 


Thanks for the response!

But if energy goes into making the molecules vibrate back and forth more energetically, doesn't that increase temperature (since temperature is average kinetic energy)?

In other words, if all the energy goes into kinetic energy -- and temperature is average kinetic energy -- how could the same amount of energy cause the temperature of different materials to rise by different amounts?
 
Christopher M said:
Thanks for the response!

But if energy goes into making the molecules vibrate back and forth more energetically, doesn't that increase temperature (since temperature is average kinetic energy)?

In other words, if all the energy goes into kinetic energy -- and temperature is average kinetic energy -- how could the same amount of energy cause the temperature of different materials to rise by different amounts?

Hi Christopher! :smile:

Because only the translational vibrations determine the temperature (vie the Boltzmann equation), but a lot of the energy goes into rotational and other internal modes. For more detail, see wikipedia:

http://en.wikipedia.org/wiki/Thermo...ernal_motions_of_molecules_and_specific_heat" :smile:
 
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