Evidence for strong electronic correlations in the bulk state of grey arsenic

Minhee Kang; Hayoon Im; Ji Eun Lee; Sung Kwan Mo; Jonathan Denlinger; Kyoo Kim; Pavel Dudin; Jose Ávila; Haeyong Kang; Jaekwang Lee; Jong Mok Ok; Xuetao Zhu; Jiandong Guo; Choongyu Hwang

doi:10.1007/s40042-026-01593-w

Evidence for strong electronic correlations in the bulk state of grey arsenic

Minhee Kang
, Hayoon Im
, Ji Eun Lee
, Sung Kwan Mo
, Jonathan Denlinger
, Kyoo Kim
, Pavel Dudin
, Jose Ávila
, Haeyong Kang
, Jaekwang Lee
, Jong Mok Ok
, Xuetao Zhu
, Jiandong Guo
, Choongyu Hwang

Department of Physics

Pusan National University
United States Department of Energy
Korea Atomic Energy Research Institute
St Aubin BP48
CAS - Institute of Physics

Research output: Contribution to journal › Article › peer-review

Abstract

We investigate the electron band structure of grey arsenic, whose (111) face hosts the topological Shockley state. Interestingly, the bulk band close to the touching point with the surface state exhibits the characteristics of inelastic scattering. Moreover, the band structure analysis reveals linearity in the imaginary part of electron self-energy. These features are analogous to those observed in high-temperature superconductors and marginal Fermi liquid systems, respectively, where strong electronic correlations exist. Our results suggest that correlated many-body states can be connected by non-interacting topological states, providing a viable playground to explore the coupling between topological and correlated states via grey arsenic surface.

Original language	English
Journal	Journal of the Korean Physical Society
DOIs	https://doi.org/10.1007/s40042-026-01593-w
State	Accepted/In press - 2026

Keywords

ARPES
Electronic correlations
Grey arsenic
Topological surface state

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10.1007/s40042-026-01593-w

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title = "Evidence for strong electronic correlations in the bulk state of grey arsenic",

abstract = "We investigate the electron band structure of grey arsenic, whose (111) face hosts the topological Shockley state. Interestingly, the bulk band close to the touching point with the surface state exhibits the characteristics of inelastic scattering. Moreover, the band structure analysis reveals linearity in the imaginary part of electron self-energy. These features are analogous to those observed in high-temperature superconductors and marginal Fermi liquid systems, respectively, where strong electronic correlations exist. Our results suggest that correlated many-body states can be connected by non-interacting topological states, providing a viable playground to explore the coupling between topological and correlated states via grey arsenic surface.",

keywords = "ARPES, Electronic correlations, Grey arsenic, Topological surface state",

author = "Minhee Kang and Hayoon Im and Lee, \{Ji Eun\} and Mo, \{Sung Kwan\} and Jonathan Denlinger and Kyoo Kim and Pavel Dudin and Jose {\'A}vila and Haeyong Kang and Jaekwang Lee and Ok, \{Jong Mok\} and Xuetao Zhu and Jiandong Guo and Choongyu Hwang",

note = "Publisher Copyright: {\textcopyright} The Korean Physical Society 2026.",

year = "2026",

doi = "10.1007/s40042-026-01593-w",

language = "English",

journal = "Journal of the Korean Physical Society",

issn = "0374-4884",

publisher = "Korean Physical Society",

}

TY - JOUR

T1 - Evidence for strong electronic correlations in the bulk state of grey arsenic

AU - Kang, Minhee

AU - Im, Hayoon

AU - Lee, Ji Eun

AU - Mo, Sung Kwan

AU - Denlinger, Jonathan

AU - Kim, Kyoo

AU - Dudin, Pavel

AU - Ávila, Jose

AU - Kang, Haeyong

AU - Lee, Jaekwang

AU - Ok, Jong Mok

AU - Zhu, Xuetao

AU - Guo, Jiandong

AU - Hwang, Choongyu

PY - 2026

Y1 - 2026

N2 - We investigate the electron band structure of grey arsenic, whose (111) face hosts the topological Shockley state. Interestingly, the bulk band close to the touching point with the surface state exhibits the characteristics of inelastic scattering. Moreover, the band structure analysis reveals linearity in the imaginary part of electron self-energy. These features are analogous to those observed in high-temperature superconductors and marginal Fermi liquid systems, respectively, where strong electronic correlations exist. Our results suggest that correlated many-body states can be connected by non-interacting topological states, providing a viable playground to explore the coupling between topological and correlated states via grey arsenic surface.

AB - We investigate the electron band structure of grey arsenic, whose (111) face hosts the topological Shockley state. Interestingly, the bulk band close to the touching point with the surface state exhibits the characteristics of inelastic scattering. Moreover, the band structure analysis reveals linearity in the imaginary part of electron self-energy. These features are analogous to those observed in high-temperature superconductors and marginal Fermi liquid systems, respectively, where strong electronic correlations exist. Our results suggest that correlated many-body states can be connected by non-interacting topological states, providing a viable playground to explore the coupling between topological and correlated states via grey arsenic surface.

KW - ARPES

KW - Electronic correlations

KW - Grey arsenic

KW - Topological surface state

UR - https://www.scopus.com/pages/publications/105031509879

U2 - 10.1007/s40042-026-01593-w

DO - 10.1007/s40042-026-01593-w

M3 - Article

AN - SCOPUS:105031509879

SN - 0374-4884

JO - Journal of the Korean Physical Society

JF - Journal of the Korean Physical Society

ER -

Evidence for strong electronic correlations in the bulk state of grey arsenic

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Keywords

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