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Autori principali: Kapetanović, Edin, Gigante, Guglielmo Nicola, Schüler, Malte, Wehling, Tim O., van Loon, Erik
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2409.05640
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author Kapetanović, Edin
Gigante, Guglielmo Nicola
Schüler, Malte
Wehling, Tim O.
van Loon, Erik
author_facet Kapetanović, Edin
Gigante, Guglielmo Nicola
Schüler, Malte
Wehling, Tim O.
van Loon, Erik
contents Electronic correlations arise from the competition between the electrons' kinetic and Coulomb interaction energy and give rise to a rich phase diagram and many emergent quasiparticles. The binding of doubly-occupied and empty sites into a doublon-holon exciton is an example of this in the Hubbard model. Unlike traditional excitons in semiconductors, in the Hubbard model it is the kinetic energy which provides the binding energy. Upon doping, we find the emergence of exciton complexes, such as a holon-doublon-holon trion. The appearance of these low-lying collective excitations make screening more effective in the doped system. As a result, Hubbard-based modelling of correlated materials should use different values of $U$ for the doped system and the insulating parent compound, which we illustrate using the cuprates as an example.
format Preprint
id arxiv_https___arxiv_org_abs_2409_05640
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Charge correlation, doublon-holon binding and screening in the doped Hubbard model
Kapetanović, Edin
Gigante, Guglielmo Nicola
Schüler, Malte
Wehling, Tim O.
van Loon, Erik
Strongly Correlated Electrons
Electronic correlations arise from the competition between the electrons' kinetic and Coulomb interaction energy and give rise to a rich phase diagram and many emergent quasiparticles. The binding of doubly-occupied and empty sites into a doublon-holon exciton is an example of this in the Hubbard model. Unlike traditional excitons in semiconductors, in the Hubbard model it is the kinetic energy which provides the binding energy. Upon doping, we find the emergence of exciton complexes, such as a holon-doublon-holon trion. The appearance of these low-lying collective excitations make screening more effective in the doped system. As a result, Hubbard-based modelling of correlated materials should use different values of $U$ for the doped system and the insulating parent compound, which we illustrate using the cuprates as an example.
title Charge correlation, doublon-holon binding and screening in the doped Hubbard model
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2409.05640