Title
Orbital Ingredients and Persistent Dirac Surface State for the Topological Band Structure in FeTe0.55Se0.45Author
Other institutions
https://ror.org/00f54p054https://ror.org/01an7q238
https://ror.org/02e24yw40
https://ror.org/02e24yw40
https://ror.org/04p491231
Version
Published versionDocument type
Journal ArticleLanguage
EnglishRights
© The Author(s)Access
Open accessPublisher’s version
https://doi.org/10.1103/PhysRevX.14.021043Published at
Physical Review X 2021 Vol. 14. N. art 021043Publisher
APSKeywords
Crystal symmetry
Electronic structure
Iron compounds
Iron-based Superconductors ... [+]
Electronic structure
Iron compounds
Iron-based Superconductors ... [+]
Crystal symmetry
Electronic structure
Iron compounds
Iron-based Superconductors
Photoelectron spectroscopy
Selenium compounds
Surface states
Tellurium compounds
Topology [-]
Electronic structure
Iron compounds
Iron-based Superconductors
Photoelectron spectroscopy
Selenium compounds
Surface states
Tellurium compounds
Topology [-]
Subject (UNESCO Thesaurus)
http://vocabularies.unesco.org/thesaurus/concept17168Abstract
FeTe0.55Se0.45 (FTS) occupies a special spot in modern condensed matter physics at the intersections of electron correlation, topology, and unconventional superconductivity. The bulk electronic struct ... [+]
FeTe0.55Se0.45 (FTS) occupies a special spot in modern condensed matter physics at the intersections of electron correlation, topology, and unconventional superconductivity. The bulk electronic structure of FTS is predicted to be topologically nontrivial due to the band inversion between the dxz and pz bands along Γ-Z. However, there remain debates in both the authenticity of the Dirac surface states (DSSs) and the experimental deviations of band structure from the theoretical band inversion picture. Here we resolve these debates through a comprehensive angle-resolved photoemission spectroscopy investigation. We first observe a persistent DSS independent of kz. Then, by comparing FTS with FeSe, which has no band inversion along Γ-Z, we identify the spectral weight fingerprint of both the presence of the pz band and the inversion between the dxz and pz bands. Furthermore, we propose a renormalization scheme for the band structure under the framework of a tight-binding model preserving crystal symmetry. Our results highlight the significant influence of correlation on modifying the band structure and make a strong case for the existence of topological band structure in this unconventional superconductor. [-]
Program
EXCELLENT SCIENCE - European Research Council (ERC)Number
101020833Project
SuperFlatCollections
- Articles - Engineering [930]
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