Relationship between Imaginary Time Green's function and Average Occupancy

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Discussion Overview

The discussion revolves around the relationship between the Green's function and the average occupancy of energy levels within the context of Fermi Liquid Theory. Participants explore both non-interacting and interacting cases, seeking to clarify the origins and implications of the stated relationship.

Discussion Character

  • Exploratory, Technical explanation, Conceptual clarification

Main Points Raised

  • One participant notes the relationship between the average occupancy and the Green's function as given by the equation <n_k> = G(k, τ→0+).
  • Another participant explains that the Green's function can be defined in terms of the particle density, suggesting a foundational link between the two concepts.
  • A participant highlights the complexity of the relationship in the interacting case, mentioning the spectral function as a potential factor in understanding the average occupancy.
  • There is a suggestion to express the earlier points in momentum space, indicating a shift in perspective or approach to the problem.

Areas of Agreement / Disagreement

Participants express differing views on the complexity of the relationship in interacting versus non-interacting cases, indicating that the discussion remains unresolved regarding the specifics of the relationship and its implications.

Contextual Notes

The discussion does not resolve the assumptions underlying the relationship between the Green's function and average occupancy, particularly in the interacting case, and the dependence on the spectral function is noted but not fully explored.

a2009
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Hello everyone,

In Fermi Liquid Theory, I'm trying to understand what the relationship is between the Green's function and the average occupancy of levels. In my lecture they gave the relation

\left\langle n_k \right\rangle = G(k,\tau\rightarrow 0^+)

Anyone know where this comes from?

Thanks!
 
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This is almost by definition. The Green's function is G(x, x') = -i <T(ψ(x)ψ+(x'))>. The particle density is n(x) = -i <ψ(x)ψ+(x)>. If you let x→x' and t→t' in G, you get n!
 
Thanks for the reply. Actually I was referring to the average occupation. In the non-interacting case

n=(e^{\beta (\epsilon -\mu)}+1)^{-1}

In the interacting case it is not so simple. But this relationship was stated. I think it has to do with the spectral function.

Thanks again for any help.
 
Just rewrite what I said in momentum space.
 

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