Hybrid nodal loop metal: Unconventional magnetoresponse and material realization

Xiaoming Zhang; Zhi Ming Yu; Yunhao Lu; Xian Lei Sheng; Hui Ying Yang; Shengyuan A. Yang

doi:10.1103/PhysRevB.97.125143

Hybrid nodal loop metal: Unconventional magnetoresponse and material realization

Xiaoming Zhang, Zhi Ming Yu, Yunhao Lu, Xian Lei Sheng, Hui Ying Yang, Shengyuan A. Yang

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

85 Citations (Scopus)

Abstract

A nodal loop is formed by a band crossing along a one-dimensional closed manifold, with each point on the loop a linear nodal point in the transverse dimensions, and can be classified as type I or type II depending on the band dispersion. Here, we propose a class of nodal loops composed of both type-I and type-II points, which are hence termed as hybrid nodal loops. Based on first-principles calculations, we predict the realization of such loops in the existing electride material Ca2As. For a hybrid loop, the Fermi surface consists of coexisting electron and hole pockets that touch at isolated points for an extended range of Fermi energies, without the need for fine-tuning. This leads to unconventional magnetic responses, including the zero-field magnetic breakdown and the momentum-space Klein tunneling observable in the magnetic quantum oscillations, as well as the peculiar anisotropy in the cyclotron resonance.

Original language	English
Article number	125143
Journal	Physical Review B
Volume	97
Issue number	12
DOIs	https://doi.org/10.1103/PhysRevB.97.125143
Publication status	Published - 26 Mar 2018
Externally published	Yes

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title = "Hybrid nodal loop metal: Unconventional magnetoresponse and material realization",

abstract = "A nodal loop is formed by a band crossing along a one-dimensional closed manifold, with each point on the loop a linear nodal point in the transverse dimensions, and can be classified as type I or type II depending on the band dispersion. Here, we propose a class of nodal loops composed of both type-I and type-II points, which are hence termed as hybrid nodal loops. Based on first-principles calculations, we predict the realization of such loops in the existing electride material Ca2As. For a hybrid loop, the Fermi surface consists of coexisting electron and hole pockets that touch at isolated points for an extended range of Fermi energies, without the need for fine-tuning. This leads to unconventional magnetic responses, including the zero-field magnetic breakdown and the momentum-space Klein tunneling observable in the magnetic quantum oscillations, as well as the peculiar anisotropy in the cyclotron resonance.",

author = "Xiaoming Zhang and Yu, {Zhi Ming} and Yunhao Lu and Sheng, {Xian Lei} and Yang, {Hui Ying} and Yang, {Shengyuan A.}",

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doi = "10.1103/PhysRevB.97.125143",

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T1 - Hybrid nodal loop metal

T2 - Unconventional magnetoresponse and material realization

AU - Zhang, Xiaoming

AU - Yu, Zhi Ming

AU - Lu, Yunhao

AU - Sheng, Xian Lei

AU - Yang, Hui Ying

AU - Yang, Shengyuan A.

PY - 2018/3/26

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AB - A nodal loop is formed by a band crossing along a one-dimensional closed manifold, with each point on the loop a linear nodal point in the transverse dimensions, and can be classified as type I or type II depending on the band dispersion. Here, we propose a class of nodal loops composed of both type-I and type-II points, which are hence termed as hybrid nodal loops. Based on first-principles calculations, we predict the realization of such loops in the existing electride material Ca2As. For a hybrid loop, the Fermi surface consists of coexisting electron and hole pockets that touch at isolated points for an extended range of Fermi energies, without the need for fine-tuning. This leads to unconventional magnetic responses, including the zero-field magnetic breakdown and the momentum-space Klein tunneling observable in the magnetic quantum oscillations, as well as the peculiar anisotropy in the cyclotron resonance.

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Hybrid nodal loop metal: Unconventional magnetoresponse and material realization

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