Chiral magnetoresistance in the Weyl semimetal NbP

Anna Corinna Niemann; Johannes Gooth; Shu Chun Wu; Svenja Bäßler; Philip Sergelius; Ruben Hühne; Bernd Rellinghaus; Chandra Shekhar; Vicky Süß; Marcus Schmidt; Claudia Felser; Binghai Yan; Kornelius Nielsch

doi:10.1038/srep43394

Chiral magnetoresistance in the Weyl semimetal NbP

Anna Corinna Niemann, Johannes Gooth, Shu Chun Wu, Svenja Bäßler, Philip Sergelius, Ruben Hühne, Bernd Rellinghaus, Chandra Shekhar, Vicky Süß, Marcus Schmidt, Claudia Felser, Binghai Yan, Kornelius Nielsch

Physics

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

72 Scopus citations

Abstract

NbP is a recently realized Weyl semimetal (WSM), hosting Weyl points through which conduction and valence bands cross linearly in the bulk and exotic Fermi arcs appear. The most intriguing transport phenomenon of a WSM is the chiral anomaly-induced negative magnetoresistance (NMR) in parallel electric and magnetic fields. In intrinsic NbP the Weyl points lie far from the Fermi energy, making chiral magneto-transport elusive. Here, we use Ga-doping to relocate the Fermi energy in NbP sufficiently close to the W2 Weyl points, for which the different Fermi surfaces are verified by resultant quantum oscillations. Consequently, we observe a NMR for parallel electric and magnetic fields, which is considered as a signature of the chiral anomaly in condensed-matter physics. The NMR survives up to room temperature, making NbP a versatile material platform for the development of Weyltronic applications.

Original language	English (US)
Article number	43394
Journal	Scientific reports
Volume	7
DOIs	https://doi.org/10.1038/srep43394
State	Published - Mar 6 2017

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title = "Chiral magnetoresistance in the Weyl semimetal NbP",

abstract = "NbP is a recently realized Weyl semimetal (WSM), hosting Weyl points through which conduction and valence bands cross linearly in the bulk and exotic Fermi arcs appear. The most intriguing transport phenomenon of a WSM is the chiral anomaly-induced negative magnetoresistance (NMR) in parallel electric and magnetic fields. In intrinsic NbP the Weyl points lie far from the Fermi energy, making chiral magneto-transport elusive. Here, we use Ga-doping to relocate the Fermi energy in NbP sufficiently close to the W2 Weyl points, for which the different Fermi surfaces are verified by resultant quantum oscillations. Consequently, we observe a NMR for parallel electric and magnetic fields, which is considered as a signature of the chiral anomaly in condensed-matter physics. The NMR survives up to room temperature, making NbP a versatile material platform for the development of Weyltronic applications.",

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T1 - Chiral magnetoresistance in the Weyl semimetal NbP

AU - Niemann, Anna Corinna

AU - Gooth, Johannes

AU - Wu, Shu Chun

AU - Bäßler, Svenja

AU - Sergelius, Philip

AU - Hühne, Ruben

AU - Rellinghaus, Bernd

AU - Shekhar, Chandra

AU - Süß, Vicky

AU - Schmidt, Marcus

AU - Felser, Claudia

AU - Yan, Binghai

AU - Nielsch, Kornelius

PY - 2017/3/6

Y1 - 2017/3/6

N2 - NbP is a recently realized Weyl semimetal (WSM), hosting Weyl points through which conduction and valence bands cross linearly in the bulk and exotic Fermi arcs appear. The most intriguing transport phenomenon of a WSM is the chiral anomaly-induced negative magnetoresistance (NMR) in parallel electric and magnetic fields. In intrinsic NbP the Weyl points lie far from the Fermi energy, making chiral magneto-transport elusive. Here, we use Ga-doping to relocate the Fermi energy in NbP sufficiently close to the W2 Weyl points, for which the different Fermi surfaces are verified by resultant quantum oscillations. Consequently, we observe a NMR for parallel electric and magnetic fields, which is considered as a signature of the chiral anomaly in condensed-matter physics. The NMR survives up to room temperature, making NbP a versatile material platform for the development of Weyltronic applications.

AB - NbP is a recently realized Weyl semimetal (WSM), hosting Weyl points through which conduction and valence bands cross linearly in the bulk and exotic Fermi arcs appear. The most intriguing transport phenomenon of a WSM is the chiral anomaly-induced negative magnetoresistance (NMR) in parallel electric and magnetic fields. In intrinsic NbP the Weyl points lie far from the Fermi energy, making chiral magneto-transport elusive. Here, we use Ga-doping to relocate the Fermi energy in NbP sufficiently close to the W2 Weyl points, for which the different Fermi surfaces are verified by resultant quantum oscillations. Consequently, we observe a NMR for parallel electric and magnetic fields, which is considered as a signature of the chiral anomaly in condensed-matter physics. The NMR survives up to room temperature, making NbP a versatile material platform for the development of Weyltronic applications.

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Chiral magnetoresistance in the Weyl semimetal NbP

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