Experimental observation of node-line-like surface states in LaBi

Baojie Feng; Jin Cao; Meng Yang; Ya Feng; Shilong Wu; Botao Fu; Masashi Arita; Koji Miyamoto; Shaolong He; Kenya Shimada; Youguo Shi; Taichi Okuda; Yugui Yao

doi:10.1103/PhysRevB.97.155153

Experimental observation of node-line-like surface states in LaBi

Baojie Feng, Jin Cao, Meng Yang, Ya Feng, Shilong Wu, Botao Fu, Masashi Arita, Koji Miyamoto, Shaolong He, Kenya Shimada, Youguo Shi, Taichi Okuda, Yugui Yao

School of Physics

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

20 Citations (Scopus)

Abstract

In a Dirac nodal line semimetal, the bulk conduction and valence bands touch at extended lines in the Brillouin zone. To date, most of the theoretically predicted and experimentally discovered nodal lines derive from the bulk bands of two- and three-dimensional materials. Here, based on combined angle-resolved photoemission spectroscopy measurements and first-principles calculations, we report the discovery of node-line-like surface states on the (001) surface of LaBi. Our first-principles calculations show that these surface states become topologically trivial because of band hybridization. Our calculations also reveal that these "nodal lines" have a tiny gap, which is beyond typical experimental resolution. These results may provide important information to understand the extraordinary physical properties of LaBi, such as the extremely large magnetoresistance and resistivity plateau.

Original language	English
Article number	155153
Journal	Physical Review B
Volume	97
Issue number	15
DOIs	https://doi.org/10.1103/PhysRevB.97.155153
Publication status	Published - 25 Apr 2018

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title = "Experimental observation of node-line-like surface states in LaBi",

abstract = "In a Dirac nodal line semimetal, the bulk conduction and valence bands touch at extended lines in the Brillouin zone. To date, most of the theoretically predicted and experimentally discovered nodal lines derive from the bulk bands of two- and three-dimensional materials. Here, based on combined angle-resolved photoemission spectroscopy measurements and first-principles calculations, we report the discovery of node-line-like surface states on the (001) surface of LaBi. Our first-principles calculations show that these surface states become topologically trivial because of band hybridization. Our calculations also reveal that these {"}nodal lines{"} have a tiny gap, which is beyond typical experimental resolution. These results may provide important information to understand the extraordinary physical properties of LaBi, such as the extremely large magnetoresistance and resistivity plateau.",

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AU - Feng, Baojie

AU - Cao, Jin

AU - Yang, Meng

AU - Feng, Ya

AU - Wu, Shilong

AU - Fu, Botao

AU - Arita, Masashi

AU - Miyamoto, Koji

AU - He, Shaolong

AU - Shimada, Kenya

AU - Shi, Youguo

AU - Okuda, Taichi

AU - Yao, Yugui

PY - 2018/4/25

Y1 - 2018/4/25

N2 - In a Dirac nodal line semimetal, the bulk conduction and valence bands touch at extended lines in the Brillouin zone. To date, most of the theoretically predicted and experimentally discovered nodal lines derive from the bulk bands of two- and three-dimensional materials. Here, based on combined angle-resolved photoemission spectroscopy measurements and first-principles calculations, we report the discovery of node-line-like surface states on the (001) surface of LaBi. Our first-principles calculations show that these surface states become topologically trivial because of band hybridization. Our calculations also reveal that these "nodal lines" have a tiny gap, which is beyond typical experimental resolution. These results may provide important information to understand the extraordinary physical properties of LaBi, such as the extremely large magnetoresistance and resistivity plateau.

AB - In a Dirac nodal line semimetal, the bulk conduction and valence bands touch at extended lines in the Brillouin zone. To date, most of the theoretically predicted and experimentally discovered nodal lines derive from the bulk bands of two- and three-dimensional materials. Here, based on combined angle-resolved photoemission spectroscopy measurements and first-principles calculations, we report the discovery of node-line-like surface states on the (001) surface of LaBi. Our first-principles calculations show that these surface states become topologically trivial because of band hybridization. Our calculations also reveal that these "nodal lines" have a tiny gap, which is beyond typical experimental resolution. These results may provide important information to understand the extraordinary physical properties of LaBi, such as the extremely large magnetoresistance and resistivity plateau.

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Experimental observation of node-line-like surface states in LaBi

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