Revealing the band structure of ZrTe\(_5\) using Multicarrier Transport

Revealing the band structure of ZrTe\(_5\) using Multicarrier Transport

The layered material ZrTe\(_5\) appears to exhibit several exotic behaviors which resulted in significant interest recently, although the exact properties are still highly debated. Among these we find a Dirac/Weyl semimetallic behavior, nontrivial spin textures revealed by low temperature transport,...

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Veröffentlicht in:arXiv.org 2023-01
Hauptverfasser: Kovács-Krausz, Zoltán, Tóvári, Endre, Nagy, Dániel, Albin Márffy, Karpiak, Bogdan, Tajkov, Zoltán, Oroszlány, László, Koltai, János, Nemes-Incze, Péter, Dash, Saroj, Makk, Péter, Csonka, Szabolcs
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Band structure of solids
Electronic structure
Fermi surfaces
Low temperature
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creator Kovács-Krausz, Zoltán
Tóvári, Endre
Nagy, Dániel
Albin Márffy
Karpiak, Bogdan
Tajkov, Zoltán
Oroszlány, László
Koltai, János
Nemes-Incze, Péter
Dash, Saroj
Makk, Péter
Csonka, Szabolcs
description The layered material ZrTe\(_5\) appears to exhibit several exotic behaviors which resulted in significant interest recently, although the exact properties are still highly debated. Among these we find a Dirac/Weyl semimetallic behavior, nontrivial spin textures revealed by low temperature transport, and a potential weak or strong topological phase. The anomalous behavior of resistivity has been recently elucidated as originating from band shifting in the electronic structure. Our work examines magnetotransport behavior in ZrTe\(_5\) samples in the context of multicarrier transport. The results, in conjunction with ab-initio band structure calculations, indicate that many of the transport features of ZrTe\(_5\) across the majority of the temperature range can be adequately explained by the semiclassical multicarrier transport model originating from a complex Fermi surface.
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Electronic structure
Fermi surfaces
Low temperature
title Revealing the band structure of ZrTe\(_5\) using Multicarrier Transport
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