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Main Authors: Sellié, Pierre, Berger, J. Arjan, Romaniello, Pina
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.01085
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author Sellié, Pierre
Berger, J. Arjan
Romaniello, Pina
author_facet Sellié, Pierre
Berger, J. Arjan
Romaniello, Pina
contents Several photoemission spectroscopies and, in particular, Auger spectroscopy, involve double-ionization processes. For the numerical simulation of these spectroscopies it is convenient to use the particle-particle channel of the two-body Green's functions since its poles correspond to excitation energies in which the final state has two more particles (holes or electrons) than the initial state. In standard approaches it is approximated within the random phase approximation. As a consequence only the quasiparticles of the photoemission spectrum are captured but none of the satellites features. In this work, we go beyond this approximation by employing the multichannel Dyson equation. By coupling the particle-particle two-body Green's function to the 3-hole-1-electron and 3-electron-1-hole channels of the four-body Green's function, the multichannel Dyson equation incorporates correlations beyond the RPA in a straightforward way. We are thus able to describe both quasiparticles and satellites in the photoemission spectra.
format Preprint
id arxiv_https___arxiv_org_abs_2604_01085
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle The multichannel Dyson equation for double ionisation spectroscopies
Sellié, Pierre
Berger, J. Arjan
Romaniello, Pina
Strongly Correlated Electrons
Several photoemission spectroscopies and, in particular, Auger spectroscopy, involve double-ionization processes. For the numerical simulation of these spectroscopies it is convenient to use the particle-particle channel of the two-body Green's functions since its poles correspond to excitation energies in which the final state has two more particles (holes or electrons) than the initial state. In standard approaches it is approximated within the random phase approximation. As a consequence only the quasiparticles of the photoemission spectrum are captured but none of the satellites features. In this work, we go beyond this approximation by employing the multichannel Dyson equation. By coupling the particle-particle two-body Green's function to the 3-hole-1-electron and 3-electron-1-hole channels of the four-body Green's function, the multichannel Dyson equation incorporates correlations beyond the RPA in a straightforward way. We are thus able to describe both quasiparticles and satellites in the photoemission spectra.
title The multichannel Dyson equation for double ionisation spectroscopies
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2604.01085