Photoemission Spectra from the Extended Koopman’s Theorem, Revisited

Photoemission Spectra from the Extended Koopman’s Theorem, Revisited

The Extended Koopman’s Theorem (EKT) provides a straightforward way to compute charged excitations from any level of theory. In this work we make the link with the many-body effective energy theory (MEET) that we derived to calculate the spectral function, which is directly related to photoemission...

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Veröffentlicht in:Frontiers in chemistry 2021-10, Vol.9, p.746735-746735
Hauptverfasser: Di Sabatino, S., Koskelo, J., Prodhon, J., Berger, J. A., Caffarel, M., Romaniello, P.
Format: Artikel
Sprache:eng
Schlagworte:
Chemistry
Condensed Matter
extended Koopman’s theorem
one-body Green’s function
photoemission
Physics
QMC
RDMFT
strong correlation
Strongly Correlated Electrons
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Zusammenfassung:The Extended Koopman’s Theorem (EKT) provides a straightforward way to compute charged excitations from any level of theory. In this work we make the link with the many-body effective energy theory (MEET) that we derived to calculate the spectral function, which is directly related to photoemission spectra. In particular, we show that at its lowest level of approximation the MEET removal and addition energies correspond to the so-called diagonal approximation of the EKT. Thanks to this link, the EKT and the MEET can benefit from mutual insight. In particular, one can readily extend the EKT to calculate the full spectral function, and choose a more optimal basis set for the MEET by solving the EKT secular equation. We illustrate these findings with the examples of the Hubbard dimer and bulk silicon.
ISSN:2296-2646
2296-2646
DOI:10.3389/fchem.2021.746735