Unconventional exciton evolution from the pseudogap to superconducting phases in cuprates

A. Singh; H. Y. Huang; J. D. Xie; J. Okamoto; C. T. Chen; T. Watanabe; A. Fujimori; M. Imada; D. J. Huang

doi:10.1038/s41467-022-35210-8

Unconventional exciton evolution from the pseudogap to superconducting phases in cuprates

A. Singh, H. Y. Huang, J. D. Xie, J. Okamoto, C. T. Chen, T. Watanabe, A. Fujimori^*, M. Imada^*, D. J. Huang^*

^*Corresponding author for this work

Waseda Research Institute for Science and Engineering

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

Abstract

Electron quasiparticles play a crucial role in simplifying the description of many-body physics in solids with surprising success. Conventional Landau’s Fermi-liquid and quasiparticle theories for high-temperature superconducting cuprates have, however, received skepticism from various angles. A path-breaking framework of electron fractionalization has been established to replace the Fermi-liquid theory for systems that show the fractional quantum Hall effect and the Mott insulating phenomena; whether it captures the essential physics of the pseudogap and superconducting phases of cuprates is still an open issue. Here, we show that excitonic excitation of optimally doped Bi₂Sr₂CaCu₂O_8+δ with energy far above the superconducting-gap energy scale, about 1 eV or even higher, is unusually enhanced by the onset of superconductivity. Our finding proves the involvement of such high-energy excitons in superconductivity. Therefore, the observed enhancement in the spectral weight of excitons imposes a crucial constraint on theories for the pseudogap and superconducting mechanisms. A simple two-component fermion model which embodies electron fractionalization in the pseudogap state provides a possible mechanism of this enhancement, pointing toward a novel route for understanding the electronic structure of superconducting cuprates.

Original language	English
Article number	7906
Journal	Nature communications
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-35210-8
Publication status	Published - 2022 Dec

ASJC Scopus subject areas

Chemistry(all)
Biochemistry, Genetics and Molecular Biology(all)
General
Physics and Astronomy(all)

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title = "Unconventional exciton evolution from the pseudogap to superconducting phases in cuprates",

abstract = "Electron quasiparticles play a crucial role in simplifying the description of many-body physics in solids with surprising success. Conventional Landau{\textquoteright}s Fermi-liquid and quasiparticle theories for high-temperature superconducting cuprates have, however, received skepticism from various angles. A path-breaking framework of electron fractionalization has been established to replace the Fermi-liquid theory for systems that show the fractional quantum Hall effect and the Mott insulating phenomena; whether it captures the essential physics of the pseudogap and superconducting phases of cuprates is still an open issue. Here, we show that excitonic excitation of optimally doped Bi2Sr2CaCu2O8+δ with energy far above the superconducting-gap energy scale, about 1 eV or even higher, is unusually enhanced by the onset of superconductivity. Our finding proves the involvement of such high-energy excitons in superconductivity. Therefore, the observed enhancement in the spectral weight of excitons imposes a crucial constraint on theories for the pseudogap and superconducting mechanisms. A simple two-component fermion model which embodies electron fractionalization in the pseudogap state provides a possible mechanism of this enhancement, pointing toward a novel route for understanding the electronic structure of superconducting cuprates.",

author = "A. Singh and Huang, {H. Y.} and Xie, {J. D.} and J. Okamoto and Chen, {C. T.} and T. Watanabe and A. Fujimori and M. Imada and Huang, {D. J.}",

note = "Funding Information: This work was supported in part by the Ministry of Science and Technology of Taiwan under Grant no. 109-2112-M-213-010-MY3 and 109-2923-M-213-001. We also thank the support of KAKENHI Grant no. 15H02109, no. 16H06345, no. 19K03741, no. 20K03849, no. 22K03535, and no. 22H05114 from JSPS. One of the authors, T.W., was supported by a Hirosaki University Grant for Distinguished Researchers from fiscal year 2017 to fiscal year 2018. This research was also supported by MEXT as “Program for Promoting Researches on the Supercomputer Fugaku” (Basic Science for Emergence and Functionality in Quantum Matter - Innovative Strongly Correlated Electron Science by Integration of Fugaku and Frontier Experiments -, JPMXP1020200104) together with computational resources of supercomputer Fugaku provided by the RIKEN Center for Computational Science (Project ID: hp200132, hp210163, and hp220166). Publisher Copyright: {\textcopyright} 2022, The Author(s).",

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doi = "10.1038/s41467-022-35210-8",

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AU - Singh, A.

AU - Huang, H. Y.

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AU - Okamoto, J.

AU - Chen, C. T.

AU - Watanabe, T.

AU - Fujimori, A.

AU - Imada, M.

AU - Huang, D. J.

N1 - Funding Information: This work was supported in part by the Ministry of Science and Technology of Taiwan under Grant no. 109-2112-M-213-010-MY3 and 109-2923-M-213-001. We also thank the support of KAKENHI Grant no. 15H02109, no. 16H06345, no. 19K03741, no. 20K03849, no. 22K03535, and no. 22H05114 from JSPS. One of the authors, T.W., was supported by a Hirosaki University Grant for Distinguished Researchers from fiscal year 2017 to fiscal year 2018. This research was also supported by MEXT as “Program for Promoting Researches on the Supercomputer Fugaku” (Basic Science for Emergence and Functionality in Quantum Matter - Innovative Strongly Correlated Electron Science by Integration of Fugaku and Frontier Experiments -, JPMXP1020200104) together with computational resources of supercomputer Fugaku provided by the RIKEN Center for Computational Science (Project ID: hp200132, hp210163, and hp220166). Publisher Copyright: © 2022, The Author(s).

PY - 2022/12

Y1 - 2022/12

N2 - Electron quasiparticles play a crucial role in simplifying the description of many-body physics in solids with surprising success. Conventional Landau’s Fermi-liquid and quasiparticle theories for high-temperature superconducting cuprates have, however, received skepticism from various angles. A path-breaking framework of electron fractionalization has been established to replace the Fermi-liquid theory for systems that show the fractional quantum Hall effect and the Mott insulating phenomena; whether it captures the essential physics of the pseudogap and superconducting phases of cuprates is still an open issue. Here, we show that excitonic excitation of optimally doped Bi2Sr2CaCu2O8+δ with energy far above the superconducting-gap energy scale, about 1 eV or even higher, is unusually enhanced by the onset of superconductivity. Our finding proves the involvement of such high-energy excitons in superconductivity. Therefore, the observed enhancement in the spectral weight of excitons imposes a crucial constraint on theories for the pseudogap and superconducting mechanisms. A simple two-component fermion model which embodies electron fractionalization in the pseudogap state provides a possible mechanism of this enhancement, pointing toward a novel route for understanding the electronic structure of superconducting cuprates.

AB - Electron quasiparticles play a crucial role in simplifying the description of many-body physics in solids with surprising success. Conventional Landau’s Fermi-liquid and quasiparticle theories for high-temperature superconducting cuprates have, however, received skepticism from various angles. A path-breaking framework of electron fractionalization has been established to replace the Fermi-liquid theory for systems that show the fractional quantum Hall effect and the Mott insulating phenomena; whether it captures the essential physics of the pseudogap and superconducting phases of cuprates is still an open issue. Here, we show that excitonic excitation of optimally doped Bi2Sr2CaCu2O8+δ with energy far above the superconducting-gap energy scale, about 1 eV or even higher, is unusually enhanced by the onset of superconductivity. Our finding proves the involvement of such high-energy excitons in superconductivity. Therefore, the observed enhancement in the spectral weight of excitons imposes a crucial constraint on theories for the pseudogap and superconducting mechanisms. A simple two-component fermion model which embodies electron fractionalization in the pseudogap state provides a possible mechanism of this enhancement, pointing toward a novel route for understanding the electronic structure of superconducting cuprates.

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Unconventional exciton evolution from the pseudogap to superconducting phases in cuprates

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