Berry phase and band structure analysis of the Weyl semimetal NbP

Philip Sergelius; Johannes Gooth; Svenja B'ßler; Robert Zierold; Christoph Wiegand; Anna Niemann; Heiko Reith; Chandra Shekhar; Claudia Felser; Binghai Yan; Kornelius Nielsch

doi:10.1038/srep33859

Berry phase and band structure analysis of the Weyl semimetal NbP

Philip Sergelius, Johannes Gooth, Svenja B'ßler, Robert Zierold, Christoph Wiegand, Anna Niemann, Heiko Reith, Chandra Shekhar, Claudia Felser, Binghai Yan, Kornelius Nielsch

Physics

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37 Scopus citations

Abstract

Weyl semimetals are often considered the 3D-analogon of graphene or topological insulators. The evaluation of quantum oscillations in these systems remains challenging because there are often multiple conduction bands. We observe de Haas-van Alphen oscillations with several frequencies in a single crystal of the Weyl semimetal niobium phosphide. For each fundamental crystal axis, we can fit the raw data to a superposition of sinusoidal functions, which enables us to calculate the characteristic parameters of all individual bulk conduction bands using Fourier transform with an analysis of the temperature and magnetic field-dependent oscillation amplitude decay. Our experimental results indicate that the band structure consists of Dirac bands with low cyclotron mass, a non-trivial Berry phase and parabolic bands with a higher effective mass and trivial Berry phase.

Original language	English (US)
Article number	33859
Journal	Scientific reports
Volume	6
DOIs	https://doi.org/10.1038/srep33859
State	Published - Sep 26 2016

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title = "Berry phase and band structure analysis of the Weyl semimetal NbP",

abstract = "Weyl semimetals are often considered the 3D-analogon of graphene or topological insulators. The evaluation of quantum oscillations in these systems remains challenging because there are often multiple conduction bands. We observe de Haas-van Alphen oscillations with several frequencies in a single crystal of the Weyl semimetal niobium phosphide. For each fundamental crystal axis, we can fit the raw data to a superposition of sinusoidal functions, which enables us to calculate the characteristic parameters of all individual bulk conduction bands using Fourier transform with an analysis of the temperature and magnetic field-dependent oscillation amplitude decay. Our experimental results indicate that the band structure consists of Dirac bands with low cyclotron mass, a non-trivial Berry phase and parabolic bands with a higher effective mass and trivial Berry phase.",

author = "Philip Sergelius and Johannes Gooth and Svenja B'{\ss}ler and Robert Zierold and Christoph Wiegand and Anna Niemann and Heiko Reith and Chandra Shekhar and Claudia Felser and Binghai Yan and Kornelius Nielsch",

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doi = "10.1038/srep33859",

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T1 - Berry phase and band structure analysis of the Weyl semimetal NbP

AU - Sergelius, Philip

AU - Gooth, Johannes

AU - B'ßler, Svenja

AU - Zierold, Robert

AU - Wiegand, Christoph

AU - Niemann, Anna

AU - Reith, Heiko

AU - Shekhar, Chandra

AU - Felser, Claudia

AU - Yan, Binghai

AU - Nielsch, Kornelius

PY - 2016/9/26

Y1 - 2016/9/26

N2 - Weyl semimetals are often considered the 3D-analogon of graphene or topological insulators. The evaluation of quantum oscillations in these systems remains challenging because there are often multiple conduction bands. We observe de Haas-van Alphen oscillations with several frequencies in a single crystal of the Weyl semimetal niobium phosphide. For each fundamental crystal axis, we can fit the raw data to a superposition of sinusoidal functions, which enables us to calculate the characteristic parameters of all individual bulk conduction bands using Fourier transform with an analysis of the temperature and magnetic field-dependent oscillation amplitude decay. Our experimental results indicate that the band structure consists of Dirac bands with low cyclotron mass, a non-trivial Berry phase and parabolic bands with a higher effective mass and trivial Berry phase.

AB - Weyl semimetals are often considered the 3D-analogon of graphene or topological insulators. The evaluation of quantum oscillations in these systems remains challenging because there are often multiple conduction bands. We observe de Haas-van Alphen oscillations with several frequencies in a single crystal of the Weyl semimetal niobium phosphide. For each fundamental crystal axis, we can fit the raw data to a superposition of sinusoidal functions, which enables us to calculate the characteristic parameters of all individual bulk conduction bands using Fourier transform with an analysis of the temperature and magnetic field-dependent oscillation amplitude decay. Our experimental results indicate that the band structure consists of Dirac bands with low cyclotron mass, a non-trivial Berry phase and parabolic bands with a higher effective mass and trivial Berry phase.

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Berry phase and band structure analysis of the Weyl semimetal NbP

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