Double Dirac nodal line semimetal with a torus surface state

Xiao Ping Li; Botao Fu; Da Shuai Ma; Chaoxi Cui; Zhi Ming Yu; Yugui Yao

doi:10.1103/PhysRevB.103.L161109

Double Dirac nodal line semimetal with a torus surface state

Xiao Ping Li, Botao Fu, Da Shuai Ma, Chaoxi Cui, Zhi Ming Yu, Yugui Yao

School of Physics

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

23 Citations (Scopus)

Abstract

We propose a class of nodal line semimetals that host an eightfold-degenerate double Dirac nodal line (DDNL) with negligible spin-orbit coupling. We find only 5 of the 230 space groups host the DDNL. The DDNL can be considered as a combination of two Dirac nodal lines, and has a trivial Berry phase. This leads to two possible but completely different surface states, namely, a torus surface state covering the whole surface Brillouin zone and no surface state at all. Based on first-principles calculations, we predict that the hydrogen storage material LiBH is an ideal DDNL semimetal, where the line resides at Fermi level, is relatively flat in energy, and exhibits a large linear energy range. Interestingly, both the two novel surface states of DDNL can be realized in LiBH. Further, we predict that with a magnetic field parallel to DDNL, the Landau levels of DDNL are doubly degenerate due to a Kramers-like degeneracy and have a doubly degenerate zero mode.

Original language	English
Article number	L161109
Journal	Physical Review B
Volume	103
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevB.103.L161109
Publication status	Published - 22 Apr 2021

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title = "Double Dirac nodal line semimetal with a torus surface state",

abstract = "We propose a class of nodal line semimetals that host an eightfold-degenerate double Dirac nodal line (DDNL) with negligible spin-orbit coupling. We find only 5 of the 230 space groups host the DDNL. The DDNL can be considered as a combination of two Dirac nodal lines, and has a trivial Berry phase. This leads to two possible but completely different surface states, namely, a torus surface state covering the whole surface Brillouin zone and no surface state at all. Based on first-principles calculations, we predict that the hydrogen storage material LiBH is an ideal DDNL semimetal, where the line resides at Fermi level, is relatively flat in energy, and exhibits a large linear energy range. Interestingly, both the two novel surface states of DDNL can be realized in LiBH. Further, we predict that with a magnetic field parallel to DDNL, the Landau levels of DDNL are doubly degenerate due to a Kramers-like degeneracy and have a doubly degenerate zero mode.",

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AU - Li, Xiao Ping

AU - Fu, Botao

AU - Ma, Da Shuai

AU - Cui, Chaoxi

AU - Yu, Zhi Ming

AU - Yao, Yugui

PY - 2021/4/22

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AB - We propose a class of nodal line semimetals that host an eightfold-degenerate double Dirac nodal line (DDNL) with negligible spin-orbit coupling. We find only 5 of the 230 space groups host the DDNL. The DDNL can be considered as a combination of two Dirac nodal lines, and has a trivial Berry phase. This leads to two possible but completely different surface states, namely, a torus surface state covering the whole surface Brillouin zone and no surface state at all. Based on first-principles calculations, we predict that the hydrogen storage material LiBH is an ideal DDNL semimetal, where the line resides at Fermi level, is relatively flat in energy, and exhibits a large linear energy range. Interestingly, both the two novel surface states of DDNL can be realized in LiBH. Further, we predict that with a magnetic field parallel to DDNL, the Landau levels of DDNL are doubly degenerate due to a Kramers-like degeneracy and have a doubly degenerate zero mode.

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Double Dirac nodal line semimetal with a torus surface state

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