Identifying s-wave pairing symmetry in single-layer FeSe from topologically trivial edge states

Zhongxu Wei; Shengshan Qin; Cui Ding; Xianxin Wu; Jiangping Hu; Yu Jie Sun; Lili Wang; Qi Kun Xue

doi:10.1038/s41467-023-40931-5

Identifying s-wave pairing symmetry in single-layer FeSe from topologically trivial edge states

Zhongxu Wei, Shengshan Qin, Cui Ding, Xianxin Wu, Jiangping Hu, Yu Jie Sun^*, Lili Wang^*, Qi Kun Xue^*

^*Corresponding author for this work

School of Physics

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

3 Citations (Scopus)

Abstract

Determining the pairing symmetry of single-layer FeSe on SrTiO₃ is the key to understanding the enhanced pairing mechanism. It also guides the search for superconductors with high transition temperatures. Despite considerable efforts, it remains controversial whether the symmetry is the sign-preserving s- or the sign-changing s _±-wave. Here, we investigate the pairing symmetry of single-layer FeSe from a topological point of view. Using low-temperature scanning tunneling microscopy/spectroscopy, we systematically characterize the superconducting states at edges and corners of single-layer FeSe. The tunneling spectra collected at edges and corners show a full energy gap and a substantial dip, respectively, suggesting the absence of topologically non-trivial edge and corner modes. According to our theoretical calculations, these spectroscopic features can be considered as strong evidence for the sign-preserving s-wave pairing in single-layer FeSe.

Original language	English
Article number	5302
Journal	Nature Communications
Volume	14
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-40931-5
Publication status	Published - Dec 2023

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title = "Identifying s-wave pairing symmetry in single-layer FeSe from topologically trivial edge states",

abstract = "Determining the pairing symmetry of single-layer FeSe on SrTiO3 is the key to understanding the enhanced pairing mechanism. It also guides the search for superconductors with high transition temperatures. Despite considerable efforts, it remains controversial whether the symmetry is the sign-preserving s- or the sign-changing s ±-wave. Here, we investigate the pairing symmetry of single-layer FeSe from a topological point of view. Using low-temperature scanning tunneling microscopy/spectroscopy, we systematically characterize the superconducting states at edges and corners of single-layer FeSe. The tunneling spectra collected at edges and corners show a full energy gap and a substantial dip, respectively, suggesting the absence of topologically non-trivial edge and corner modes. According to our theoretical calculations, these spectroscopic features can be considered as strong evidence for the sign-preserving s-wave pairing in single-layer FeSe.",

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AU - Wei, Zhongxu

AU - Qin, Shengshan

AU - Ding, Cui

AU - Wu, Xianxin

AU - Hu, Jiangping

AU - Sun, Yu Jie

AU - Wang, Lili

AU - Xue, Qi Kun

PY - 2023/12

Y1 - 2023/12

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AB - Determining the pairing symmetry of single-layer FeSe on SrTiO3 is the key to understanding the enhanced pairing mechanism. It also guides the search for superconductors with high transition temperatures. Despite considerable efforts, it remains controversial whether the symmetry is the sign-preserving s- or the sign-changing s ±-wave. Here, we investigate the pairing symmetry of single-layer FeSe from a topological point of view. Using low-temperature scanning tunneling microscopy/spectroscopy, we systematically characterize the superconducting states at edges and corners of single-layer FeSe. The tunneling spectra collected at edges and corners show a full energy gap and a substantial dip, respectively, suggesting the absence of topologically non-trivial edge and corner modes. According to our theoretical calculations, these spectroscopic features can be considered as strong evidence for the sign-preserving s-wave pairing in single-layer FeSe.

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Identifying s-wave pairing symmetry in single-layer FeSe from topologically trivial edge states

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