Type-II nodal loops: Theory and material realization

Si Li; Zhi Ming Yu; Ying Liu; Shan Guan; Shan Shan Wang; Xiaoming Zhang; Yugui Yao; Shengyuan A. Yang

doi:10.1103/PhysRevB.96.081106

Type-II nodal loops: Theory and material realization

Si Li, Zhi Ming Yu, Ying Liu, Shan Guan, Shan Shan Wang, Xiaoming Zhang, Yugui Yao, Shengyuan A. Yang

School of Physics

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

181 Citations (Scopus)

Abstract

A nodal loop appears when two bands, typically one electronlike and one holelike, are crossing each other linearly along a one-dimensional manifold in reciprocal space. Here, we propose a type of nodal loop which emerges from the crossing between two bands which are both electronlike (or holelike) along a certain direction. Close to any point on such a loop (dubbed as a type-II nodal loop), the linear spectrum is strongly tilted and tipped over along one transverse direction, leading to marked differences in magnetic, optical, and transport responses compared with conventional (type-I) nodal loops. We show that the compound K4P3 is an example that hosts a pair of type-II nodal loops close to the Fermi level. Each loop traverses the whole Brillouin zone, and hence can only be annihilated in a pair when symmetry is preserved. The symmetry and topological protections of the loops as well as the associated surface states are discussed.

Original language	English
Article number	081106
Journal	Physical Review B
Volume	96
Issue number	8
DOIs	https://doi.org/10.1103/PhysRevB.96.081106
Publication status	Published - 14 Aug 2017

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abstract = "A nodal loop appears when two bands, typically one electronlike and one holelike, are crossing each other linearly along a one-dimensional manifold in reciprocal space. Here, we propose a type of nodal loop which emerges from the crossing between two bands which are both electronlike (or holelike) along a certain direction. Close to any point on such a loop (dubbed as a type-II nodal loop), the linear spectrum is strongly tilted and tipped over along one transverse direction, leading to marked differences in magnetic, optical, and transport responses compared with conventional (type-I) nodal loops. We show that the compound K4P3 is an example that hosts a pair of type-II nodal loops close to the Fermi level. Each loop traverses the whole Brillouin zone, and hence can only be annihilated in a pair when symmetry is preserved. The symmetry and topological protections of the loops as well as the associated surface states are discussed.",

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AU - Li, Si

AU - Yu, Zhi Ming

AU - Liu, Ying

AU - Guan, Shan

AU - Wang, Shan Shan

AU - Zhang, Xiaoming

AU - Yao, Yugui

AU - Yang, Shengyuan A.

PY - 2017/8/14

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AB - A nodal loop appears when two bands, typically one electronlike and one holelike, are crossing each other linearly along a one-dimensional manifold in reciprocal space. Here, we propose a type of nodal loop which emerges from the crossing between two bands which are both electronlike (or holelike) along a certain direction. Close to any point on such a loop (dubbed as a type-II nodal loop), the linear spectrum is strongly tilted and tipped over along one transverse direction, leading to marked differences in magnetic, optical, and transport responses compared with conventional (type-I) nodal loops. We show that the compound K4P3 is an example that hosts a pair of type-II nodal loops close to the Fermi level. Each loop traverses the whole Brillouin zone, and hence can only be annihilated in a pair when symmetry is preserved. The symmetry and topological protections of the loops as well as the associated surface states are discussed.

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Type-II nodal loops: Theory and material realization

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