Topological and nodal superconductor kagome magnesium triboride

Yipeng An; Juncai Chen; Zhengxuan Wang; Jie Li; Shijing Gong; Chunlan Ma; Tianxing Wang; Zhaoyong Jiao; Ruqian Wu; Jiangping Hu; Wuming Liu

doi:10.1103/PhysRevMaterials.7.014205

Topological and nodal superconductor kagome magnesium triboride

Yipeng An
, Juncai Chen
, Zhengxuan Wang
, Jie Li
, Shijing Gong
, Chunlan Ma
, Tianxing Wang
, Zhaoyong Jiao
, Ruqian Wu
, Jiangping Hu
, Wuming Liu

School of Physics and Electronic Science

Henan Normal University
University of California at Irvine
Suzhou University of Science and Technology
CAS - Institute of Physics
University of Chinese Academy of Sciences

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

15 Scopus citations

Abstract

Recently the kagome compounds have inspired enormous interest and made some great progress such as in the field of superconductivity and topology. Here we predict a different kagome magnesium triboride (MgB3) superconductor with a calculated Tc∼12.2K and Tc∼15.4 K by external stress, the potentially highest among the reported diverse kagome-type superconductors. We reveal its various exotic physical properties including the van Hove singularity, flat-band, multiple Dirac points, and nontrivial topology. The system can be described by a two-band model with highly anisotropic superconducting gaps on Fermi surfaces. Its topological and nodal superconducting nature is unveiled by a recently developed symmetry indicators method. Our results suggest that MgB3 can be a new platform to study exotic physics in the kagome structure, and pave a way to seek for more superconductors and topological materials with XY3-type kagome lattice.

Original language	English
Article number	014205
Journal	Physical Review Materials
Volume	7
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevMaterials.7.014205
State	Published - Jan 2023

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10.1103/PhysRevMaterials.7.014205

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abstract = "Recently the kagome compounds have inspired enormous interest and made some great progress such as in the field of superconductivity and topology. Here we predict a different kagome magnesium triboride (MgB3) superconductor with a calculated Tc∼12.2K and Tc∼15.4 K by external stress, the potentially highest among the reported diverse kagome-type superconductors. We reveal its various exotic physical properties including the van Hove singularity, flat-band, multiple Dirac points, and nontrivial topology. The system can be described by a two-band model with highly anisotropic superconducting gaps on Fermi surfaces. Its topological and nodal superconducting nature is unveiled by a recently developed symmetry indicators method. Our results suggest that MgB3 can be a new platform to study exotic physics in the kagome structure, and pave a way to seek for more superconductors and topological materials with XY3-type kagome lattice.",

author = "Yipeng An and Juncai Chen and Zhengxuan Wang and Jie Li and Shijing Gong and Chunlan Ma and Tianxing Wang and Zhaoyong Jiao and Ruqian Wu and Jiangping Hu and Wuming Liu",

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doi = "10.1103/PhysRevMaterials.7.014205",

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T1 - Topological and nodal superconductor kagome magnesium triboride

AU - An, Yipeng

AU - Chen, Juncai

AU - Wang, Zhengxuan

AU - Li, Jie

AU - Gong, Shijing

AU - Ma, Chunlan

AU - Wang, Tianxing

AU - Jiao, Zhaoyong

AU - Wu, Ruqian

AU - Hu, Jiangping

AU - Liu, Wuming

PY - 2023/1

Y1 - 2023/1

N2 - Recently the kagome compounds have inspired enormous interest and made some great progress such as in the field of superconductivity and topology. Here we predict a different kagome magnesium triboride (MgB3) superconductor with a calculated Tc∼12.2K and Tc∼15.4 K by external stress, the potentially highest among the reported diverse kagome-type superconductors. We reveal its various exotic physical properties including the van Hove singularity, flat-band, multiple Dirac points, and nontrivial topology. The system can be described by a two-band model with highly anisotropic superconducting gaps on Fermi surfaces. Its topological and nodal superconducting nature is unveiled by a recently developed symmetry indicators method. Our results suggest that MgB3 can be a new platform to study exotic physics in the kagome structure, and pave a way to seek for more superconductors and topological materials with XY3-type kagome lattice.

AB - Recently the kagome compounds have inspired enormous interest and made some great progress such as in the field of superconductivity and topology. Here we predict a different kagome magnesium triboride (MgB3) superconductor with a calculated Tc∼12.2K and Tc∼15.4 K by external stress, the potentially highest among the reported diverse kagome-type superconductors. We reveal its various exotic physical properties including the van Hove singularity, flat-band, multiple Dirac points, and nontrivial topology. The system can be described by a two-band model with highly anisotropic superconducting gaps on Fermi surfaces. Its topological and nodal superconducting nature is unveiled by a recently developed symmetry indicators method. Our results suggest that MgB3 can be a new platform to study exotic physics in the kagome structure, and pave a way to seek for more superconductors and topological materials with XY3-type kagome lattice.

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DO - 10.1103/PhysRevMaterials.7.014205

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JO - Physical Review Materials

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Topological and nodal superconductor kagome magnesium triboride

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