Plasmons in the Kagome metal CsV3Sb5

H. Shiravi; A. Gupta; B. R. Ortiz; S. Cui; B. Yu; E. Uykur; A. A. Tsirlin; S. D. Wilson; Z. Sun; G. X. Ni

doi:10.1038/s41467-024-49723-x

Plasmons in the Kagome metal CsV₃Sb₅

H. Shiravi
, A. Gupta
, B. R. Ortiz
, S. Cui
, B. Yu
, E. Uykur
, A. A. Tsirlin
, S. D. Wilson
, Z. Sun
, G. X. Ni

Correlated Electron Materials

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

7 Scopus citations

Abstract

Plasmon polaritons, or plasmons, are coupled oscillations of electrons and electromagnetic fields that can confine the latter into deeply subwavelength scales, enabling novel polaritonic devices. While plasmons have been extensively studied in normal metals or semimetals, they remain largely unexplored in correlated materials. In this paper, we report infrared (IR) nano-imaging of thin flakes of CsV₃Sb₅, a prototypical layered Kagome metal. We observe propagating plasmon waves in real-space with wavelengths tunable by the flake thickness. From their frequency-momentum dispersion, we infer the out-of-plane dielectric function ϵ_c that is generally difficult to obtain in conventional far-field optics, and elucidate signatures of electronic correlations when compared to density functional theory (DFT). We propose correlation effects might have switched the real part of ϵ_c from negative to positive values over a wide range of middle-IR frequencies, transforming the surface plasmons into hyperbolic bulk plasmons, and have dramatically suppressed their dissipation.

Original language	English
Article number	5389
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-49723-x
State	Published - Dec 2024

Funding

N.G.X. acknowledges discussions with K.Yang, Y.C.Wang, M.X.Ye. Research of scanning near-field nano-optical imaging studies is supported by U.S. Department of Energy (DOE) Early Career Research Program, Office of Science, Basic Energy Sciences (BES), under award DE-SC0022022 (N.G.X.). Research on 2D polaritonics is supported by the National Science Foundation (NSF) CAREER award, under award DMR-2145074 (N.G.X.). N.G.X. acknowledges the support from ACS-DNI (PRF# 66465-DNI10), the Start-Up Fund from Florida State University, and the National High Magnetic Field Laboratory (NHMFL). The NHMFL is supported by the NSF through DMR-1644779 and the state of Florida. Research at Tsinghua University is supported by the startup grant from State Key Laboratory of Low-Dimensional Quantum Physics and Tsinghua University. S.D.W. and B.R.O. gratefully acknowledge support via the UC Santa Barbara NSF Quantum Foundry funded via the Q-AMASE-i program under award DMR-1906325. B.R.O. gratefully acknowledges support from DOE/Office of Science/BES, Materials Sciences and Engineering Division.

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title = "Plasmons in the Kagome metal CsV3Sb5",

abstract = "Plasmon polaritons, or plasmons, are coupled oscillations of electrons and electromagnetic fields that can confine the latter into deeply subwavelength scales, enabling novel polaritonic devices. While plasmons have been extensively studied in normal metals or semimetals, they remain largely unexplored in correlated materials. In this paper, we report infrared (IR) nano-imaging of thin flakes of CsV3Sb5, a prototypical layered Kagome metal. We observe propagating plasmon waves in real-space with wavelengths tunable by the flake thickness. From their frequency-momentum dispersion, we infer the out-of-plane dielectric function ϵc that is generally difficult to obtain in conventional far-field optics, and elucidate signatures of electronic correlations when compared to density functional theory (DFT). We propose correlation effects might have switched the real part of ϵc from negative to positive values over a wide range of middle-IR frequencies, transforming the surface plasmons into hyperbolic bulk plasmons, and have dramatically suppressed their dissipation.",

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AU - Gupta, A.

AU - Ortiz, B. R.

AU - Cui, S.

AU - Yu, B.

AU - Uykur, E.

AU - Tsirlin, A. A.

AU - Wilson, S. D.

AU - Sun, Z.

AU - Ni, G. X.

PY - 2024/12

Y1 - 2024/12

N2 - Plasmon polaritons, or plasmons, are coupled oscillations of electrons and electromagnetic fields that can confine the latter into deeply subwavelength scales, enabling novel polaritonic devices. While plasmons have been extensively studied in normal metals or semimetals, they remain largely unexplored in correlated materials. In this paper, we report infrared (IR) nano-imaging of thin flakes of CsV3Sb5, a prototypical layered Kagome metal. We observe propagating plasmon waves in real-space with wavelengths tunable by the flake thickness. From their frequency-momentum dispersion, we infer the out-of-plane dielectric function ϵc that is generally difficult to obtain in conventional far-field optics, and elucidate signatures of electronic correlations when compared to density functional theory (DFT). We propose correlation effects might have switched the real part of ϵc from negative to positive values over a wide range of middle-IR frequencies, transforming the surface plasmons into hyperbolic bulk plasmons, and have dramatically suppressed their dissipation.

AB - Plasmon polaritons, or plasmons, are coupled oscillations of electrons and electromagnetic fields that can confine the latter into deeply subwavelength scales, enabling novel polaritonic devices. While plasmons have been extensively studied in normal metals or semimetals, they remain largely unexplored in correlated materials. In this paper, we report infrared (IR) nano-imaging of thin flakes of CsV3Sb5, a prototypical layered Kagome metal. We observe propagating plasmon waves in real-space with wavelengths tunable by the flake thickness. From their frequency-momentum dispersion, we infer the out-of-plane dielectric function ϵc that is generally difficult to obtain in conventional far-field optics, and elucidate signatures of electronic correlations when compared to density functional theory (DFT). We propose correlation effects might have switched the real part of ϵc from negative to positive values over a wide range of middle-IR frequencies, transforming the surface plasmons into hyperbolic bulk plasmons, and have dramatically suppressed their dissipation.

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Plasmons in the Kagome metal CsV₃Sb₅

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