English

The two-dimensional electron self-energy: Long-range Coulomb interaction

Strongly Correlated Electrons 2020-08-25 v2

Abstract

The electron self-energy for long-range Coulomb interactions plays a crucial role in understanding the many-body physics of interacting electron systems (e.g. in metals and semiconductors), and has been studied extensively for decades. In fact, it is among the oldest and the most-investigated many body problems in physics. However, there is a lack of an analytical expression for the self-energy ReΣ(R)(ε,T)Re \Sigma^{(R)}( \varepsilon,T) when energy ε\varepsilon and temperature kBTk_{B} T are arbitrary with respect to each other (while both being still small compared with the Fermi energy). We revisit this problem and calculate analytically the self-energy on the mass shell for a two-dimensional electron system with Coulomb interactions in the high density limit rs1r_s \ll 1, for temperature rs3/2kBT/EFrs r_s^{3/2} \ll k_{B} T/ E_F \ll r_s and energy rs3/2ε/EFrsr_s^{3/2} \ll |\varepsilon |/E_F \ll r_s. We provide the exact high-density analytical expressions for the real and imaginary parts of the electron self-energy with arbitrary value of ε/kBT\varepsilon /k_{B} T, to the leading order in the dimensionless Coulomb coupling constant rsr_s, and to several higher than leading orders in kBT/rsEFk_{B} T/r_s E_F and ε/rsEF\varepsilon /r_s E_F. We also obtain the asymptotic behavior of the self-energy in the regimes εkBT|\varepsilon | \ll k_{B} T and εkBT|\varepsilon | \gg k_{B} T. The higher-order terms have subtle and highly non-trivial compound logarithmic contributions from both ε\varepsilon and TT, explaining why they have never before been calculated in spite of the importance of the subject matter.

Keywords

Cite

@article{arxiv.2003.09433,
  title  = {The two-dimensional electron self-energy: Long-range Coulomb interaction},
  author = {Yunxiang Liao and Donovan Buterakos and Mike Schecter and Sankar Das Sarma},
  journal= {arXiv preprint arXiv:2003.09433},
  year   = {2020}
}

Comments

Published version. 16 pages, 4 figures

R2 v1 2026-06-23T14:21:52.045Z