Title
Interacting topological quantum chemistry of Mott atomic limitsAuthor
Other institutions
https://ror.org/02crff812https://ror.org/02e24yw40
https://ror.org/02e24yw40
https://ror.org/026vcq606
https://ror.org/04cvxnb49
https://ror.org/01c997669
Version
Published versionDocument type
Journal ArticleEmbargo end date
2143-01-01Language
EnglishRights
© 2023 APSAccess
Metadata only accessPublisher’s version
https://doi.org/10.1103/PhysRevB.107.245145Published at
Physical Review B 2023. Vol. 107. N.art. 245145Publisher
American Physical SocietyKeywords
Atoms
Band structure
Crystal atomic structure
Crystal symmetry ... [+]
Band structure
Crystal atomic structure
Crystal symmetry ... [+]
Atoms
Band structure
Crystal atomic structure
Crystal symmetry
Eigenvalues and eigenfunctions
Topology [-]
Band structure
Crystal atomic structure
Crystal symmetry
Eigenvalues and eigenfunctions
Topology [-]
Subject (UNESCO Thesaurus)
http://vocabularies.unesco.org/thesaurus/concept17168Abstract
Topological quantum chemistry (TQC) is a successful framework for identifying (noninteracting) topological materials. Based on the symmetry eigenvalues of Bloch eigenstates at maximal momenta, which a ... [+]
Topological quantum chemistry (TQC) is a successful framework for identifying (noninteracting) topological materials. Based on the symmetry eigenvalues of Bloch eigenstates at maximal momenta, which are attainable from first principles calculations, a band structure can either be classified as an atomic limit, in other words adiabatically connected to independent electronic orbitals on the respective crystal lattice, or it is topological. For interacting systems, there is no single-particle band structure and hence, the TQC machinery grinds to a halt. We develop a framework analogous to TQC, but employing n-particle Green's function to classify interacting systems. Fundamentally, we define a class of interacting reference states that generalize the notion of atomic limits, which we call Mott atomic limits, and are symmetry protected topological states. Our formalism allows to fully classify these reference states (with n=2), which can themselves represent symmetry protected topological states. We present a comprehensive classification of such states in one dimension and provide numerical results on model systems. With this, we establish Mott atomic limit states as a generalization of the atomic limits to interacting systems. © 2023 American Physical Society. [-]
Funder
Comisión EuropeaGobierno Español
Program
H2020PID2019
Number
10102083109905GBC21
Collections
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