Understanding the Role of Fundamental Temperature in Thermodynamics

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Discussion Overview

The discussion revolves around the concept of fundamental temperature in thermodynamics, particularly its definition and implications in equilibrium states. Participants explore theoretical aspects, the relationship between entropy and energy, and the conditions under which temperature can be defined, focusing on both coupled and uncoupled systems.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested

Main Points Raised

  • Some participants propose that the relation 1/τ = ∂σ/∂U implies that if ∂σ/∂U = 0, then temperature would be undefined.
  • Others question why ∂σ/∂U would equal zero, seeking clarification on the implications of equilibrium states.
  • One participant suggests that if the system is uncoupled, then ∂g/∂U might equal zero, raising questions about the definition of temperature in such cases.
  • Another participant notes that defining temperature becomes problematic for systems that cannot theoretically have energy added, as U would remain constant.
  • Some argue that while it may seem unreasonable to discuss the equilibrium states of an isolated system, it does not negate the existence of temperature, which remains undefined in practical terms if the system cannot be measured.
  • Participants discuss the zeroth law of thermodynamics, indicating that temperature is defined for coupled systems and that an isolated system's temperature cannot be practically measured.

Areas of Agreement / Disagreement

Participants express differing views on the implications of equilibrium states and the definition of temperature, particularly in relation to isolated versus coupled systems. There is no consensus on whether it is reasonable to speak of temperature in isolated systems, and the discussion remains unresolved.

Contextual Notes

Limitations include the dependence on definitions of temperature and equilibrium, as well as the unresolved nature of how temperature can be defined in uncoupled systems.

Gear300
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The fundamental temperature is defined so that 1/τ = ∂σ/∂U. This relation occurs as an equilibrium state, so wouldn't that imply that ∂σ/∂U = 0, leaving the temperature undefined?
 
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Gear300 said:
This relation occurs as an equilibrium state, so wouldn't that imply that ∂σ/∂U = 0

Why?
 
∂σ/∂U = 1/g(∂g/∂U), in which g is the multiplicity of states. Let us say that the system is uncoupled, then wouldn't the equilibrium condition imply ∂g/∂U = 0 (or is it that temperature is defined specifically for a coupling between systems)?
 
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I think I see what you mean. I suppose one would have a problem defining temperature for a system that one absolutely could not add energy too, even in theory. Then ∂σ/∂U would have no meaning, U being constant. But every system dealt with in practice can conceivably be heated and/or have work performed on it. If heated, the entropy of the system would increase; if reversible work were to be done, the entropy would not increase.
 
I see...so does that make it unreasonable to speak of the equilibrium states of an isolated system?
 
Gear300 said:
I see...so does that make it unreasonable to speak of the equilibrium states of an isolated system?

No, but it seems unreasonable to speak of the temperature of a system whose energy could not be altered, even in theory.
 
Gear300 said:
∂σ/∂U = 1/g(∂g/∂U), in which g is the multiplicity of states. Let us say that the system is uncoupled, then wouldn't the equilibrium condition imply ∂g/∂U = 0 (or is that temperature is defined specifically for a coupling between systems)?

Temperature is defined by the zeroth law of thermodynamics, i.e. transitivity of equilibrium: If two systems A and B are in equilibriumwhen brought into contact and B and C are also in equilibrium when brought into contact, then A and C will also be in equilibrium when brought into contact. This allows the introduction of temperature specifically for coupled systems.
 
Gear300 said:
I see...so does that make it unreasonable to speak of the equilibrium states of an isolated system?

Yes, temperature is defined in terms of systems being coupled. If two systems are thermally connected and allowed to equilibrate, their temperatures are, by the zeroth law of thermodynamics, the same. An isolated system that can never be connected to another system, can never be connected to a thermometer, and so its temperature will remain unknown, but that's a technological problem. It still has a temperature, it just cannot be practically measured.
 

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