Does internal potential energy affects temperature?

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SUMMARY

This discussion centers on the relationship between internal potential energy and temperature in physical systems. It establishes that a body with only internal potential energy can have a temperature, particularly in systems like spin-1/2 ensembles in magnetic fields. The conversation also confirms that heat can flow from an object with higher potential energy to one with kinetic energy, and that variations in potential energy can affect temperature, provided kinetic energy remains constant. The equipartition theorem is referenced to explain energy distribution among degrees of freedom in thermodynamic systems.

PREREQUISITES
  • Understanding of thermodynamic equilibrium and the equipartition theorem
  • Familiarity with concepts of internal potential and kinetic energy
  • Knowledge of spin systems and their temperature calculations
  • Basic principles of heat transfer and energy exchange
NEXT STEPS
  • Study the equipartition theorem in detail to understand energy distribution
  • Explore spin-1/2 systems and their behavior in magnetic fields
  • Research the relationship between potential energy and temperature in gases
  • Investigate the concept of degrees of freedom in thermodynamics
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Physicists, thermodynamics students, and anyone interested in the interplay between energy forms and temperature in physical systems.

tonyjk
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Hello
If I take an extreme case, where a body has only an internal potential energy with zero internal kinetic energy, does this body have a temperature? Another question related to it: if two objects A and B having different temperature: A: having only internal potential energy and B having only internal kinetic energy, can heat flow from A to B ?(temperature of A > B).
More general: Can an object at a temperature T1 (having internal kinetic energy and potential energy) have a different temperature T2 but in both case having the same internal kinetic energy and different potential energy?
Thanks
 
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tonyjk said:
If I take an extreme case, where a body has only an internal potential energy with zero internal kinetic energy, does this body have a temperature?
It can. For instance, if you have an ensemble of spin-1/2 systems in an external magnetic field, you can calculate spin temperature (beased on the ration of spin up and spin down). At the same time, it is hard for me to think of a system at thermodynamic equilibrium where you would have potential energy but no kinetic energy (because of the equipartition theorem, for instance).

tonyjk said:
Another question related to it: if two objects A and B having different temperature: A: having only internal potential energy and B having only internal kinetic energy, can heat flow from A to B ?(temperature of A > B).
If they can exchange energy, energy has to flow from A to B.

tonyjk said:
More general: Can an object at a temperature T1 (having internal kinetic energy and potential energy) have a different temperature T2 but in both case having the same internal kinetic energy and different potential energy?
Not sure I understand your question, but if you compare a solid and a gas, at the same temperature they do not have the same kinetic energy, so they will have different temperatures for the same kinetic energy.
 
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DrClaude said:
Not sure I understand your question, but if you compare a solid and a gas, at the same temperature they do not have the same kinetic energy, so they will have different temperatures for the same kinetic energy.

If we compare two solids A and B ( having the same characteristics i.e same object) , if A is at temperature 1 (T1), having a K.E1 and P.E1. B is at temperature 2 (T2) having a K.E2=K.E1 and P.E2 different to P.E1. This case is possible ?
In general : Does variating internal potential energy affects the temperature if we consider the internal kinetic energy constant?
 
tonyjk said:
In general : Does variating internal potential energy affects the temperature if we consider the internal kinetic energy constant?
In general yes: if you were somehow to pump in energy only in one kind of degree of freedom, then the system will not be in internal equilibrium anymore, and after equilibrium is reached, you will find that all degrees of freedom have increased energy, and hence the temperature is higher.
 
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DrClaude said:
In general yes: if you were somehow to pump in energy only in one kind of degree of freedom, then the system will not be in internal equilibrium anymore, and after equilibrium is reached, you will find that all degrees of freedom have increased energy, and hence the temperature is higher.
So you mean increasing potential energy will increase kinetic energy right?
 
tonyjk said:
So you mean increasing potential energy will increase kinetic energy right?
The more I think about it, the less I like this distinction you are making between potential and kinetic energy, which is why a shifted in my previous post to "degrees of freedom." For instance, if you take vibrations of atoms in a crystal, they are a constant interchange of potential and kinetic energy.

For a gas, if you take "kinetic energy" to mean the kinetic energy related to the center-of-mass motion of the gas molecules, then increasing the internal potential energy of the molecules will lead, at equilibrium, to an increase in temperature. But increasing the gravitational potential energy of the gas will not change the temperature.
 
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DrClaude said:
The more I think about it, the less I like this distinction you are making between potential and kinetic energy, which is why a shifted in my previous post to "degrees of freedom." For instance, if you take vibrations of atoms in a crystal, they are a constant interchange of potential and kinetic energy.

For a gas, if you take "kinetic energy" to mean the kinetic energy related to the center-of-mass motion of the gas molecules, then increasing the internal potential energy of the molecules will lead, at equilibrium, to an increase in temperature. But increasing the gravitational potential energy of the gas will not change the temperature.
But taking the example of a gas, increasing potential energy is due to increase in kinetic energy right?
 
Fifty years ago in high school chemistry class, we did an experiment where we dissolved a compressed spring and an uncompressed spring in acid solutions. All started at the same temperature, but the compressed spring solution had a higher temperature, attributed to the energy (potential) in the compression.
 
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