Strain-tuned topological phase transition and unconventional Zeeman effect in ZrTe5 microcrystals

Strain-tuned topological phase transition and unconventional Zeeman effect in ZrTe5 microcrystals

The geometric phase of an electronic wave function, also known as Berry phase, is the fundamental basis of the topological properties in solids. This phase can be tuned by modulating the band structure of a material, providing a way to drive a topological phase transition. However, despite significa...

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Bibliographic Details
Published in:Communications materials Vol. 3; no. 1; pp. 1 - 8
Main Authors: Gaikwad, Apurva, Sun, Song, Wang, Peipei, Zhang, Liyuan, Cano, Jennifer, Dai, Xi, Du, Xu
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 27-11-2022
Nature Publishing Group
Nature Portfolio
Subjects:
639/301/119/2792/4128
639/301/119/995
Band structure of solids
Banded structure
Chemistry and Materials Science
Magnetic properties
Materials Science
Microcrystals
Oscillations
Phase transitions
Quantum mechanics
Quantum transport
Topological insulators
Transport properties
Tuning
Wave functions
Zeeman effect
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Summary:The geometric phase of an electronic wave function, also known as Berry phase, is the fundamental basis of the topological properties in solids. This phase can be tuned by modulating the band structure of a material, providing a way to drive a topological phase transition. However, despite significant efforts in designing and understanding topological materials, it remains still challenging to tune a given material across different topological phases while tracing the impact of the Berry phase on its quantum transport properties. Here, we report these two effects in a magnetotransport study of ZrTe 5 . By tuning the band structure with uniaxial strain, we use quantum oscillations to directly map a weak-to-strong topological insulator phase transition through a gapless Dirac semimetal phase. Moreover, we demonstrate the impact of the strain-tunable spin-dependent Berry phase on the Zeeman effect through the amplitude of the quantum oscillations. We show that such a spin-dependent Berry phase, largely neglected in solid-state systems, is critical in modeling quantum oscillations in Dirac bands of topological materials. Band structure modulation may drive topological phase transitions, but tuning topological phases within the same material is challenging. Here, quantum oscillations are used to map the Berry phase and Dirac bandgap closing and reopening in a strain-induced topological insulator phase transition in ZrTe 5 .
ISSN:2662-4443
2662-4443
DOI:10.1038/s43246-022-00316-5