Revealing the topological phase diagram of ZrTe5 using the complex strain fields of microbubbles

Zoltán Tajkov; Dániel Nagy; Konrád Kandrai; János Koltai; László Oroszlány; Péter Süle; Zsolt E. Horváth; Péter Vancsó; Levente Tapasztó; Péter Nemes-Incze

doi:10.1038/s41524-022-00854-z

npj Computational Materials (Aug 2022)

Revealing the topological phase diagram of ZrTe5 using the complex strain fields of microbubbles

Zoltán Tajkov,
Dániel Nagy,
Konrád Kandrai,
János Koltai,
László Oroszlány,
Péter Süle,
Zsolt E. Horváth,
Péter Vancsó,
Levente Tapasztó,
Péter Nemes-Incze

Affiliations

Zoltán Tajkov: Centre for Energy Research, Institute of Technical Physics and Materials Science
Dániel Nagy: Department of Physics of Complex Systems, ELTE Eötvös Loránd University
Konrád Kandrai: Centre for Energy Research, Institute of Technical Physics and Materials Science
János Koltai: ELTE Eötvös Loránd University, Department of Biological Physics
László Oroszlány: Department of Physics of Complex Systems, ELTE Eötvös Loránd University
Péter Süle: Centre for Energy Research, Institute of Technical Physics and Materials Science
Zsolt E. Horváth: Centre for Energy Research, Institute of Technical Physics and Materials Science
Péter Vancsó: Centre for Energy Research, Institute of Technical Physics and Materials Science
Levente Tapasztó: Centre for Energy Research, Institute of Technical Physics and Materials Science
Péter Nemes-Incze: Centre for Energy Research, Institute of Technical Physics and Materials Science

DOI: https://doi.org/10.1038/s41524-022-00854-z
Journal volume & issue: Vol. 8, no. 1
pp. 1 – 7

Abstract

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Abstract Topological materials host robust properties, unaffected by microscopic perturbations, owing to the global topological properties of the bulk electron system. Materials in which the topological invariant can be changed by easily tuning external parameters are especially sought after. Zirconium pentatelluride (ZrTe5) is one of a few experimentally available materials that reside close to the boundary of a topological phase transition, allowing the switching of its invariant by mechanical strain. Here, we unambiguously identify a topological insulator–metal transition as a function of strain, by a combination of ab initio calculations and direct measurements of the local charge density. Our model quantitatively describes the response to complex strain patterns found in bubbles of few layer ZrTe5 without fitting parameters, reproducing the mechanical deformation-dependent closing of the band gap observed using scanning tunneling microscopy. We calculate the topological phase diagram of ZrTe5 and identify the phase at equilibrium, enabling the design of device architectures, which exploit the topological switching characteristics of the system.

Published in npj Computational Materials

ISSN: 2057-3960 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Technology: Electrical engineering. Electronics. Nuclear engineering: Materials of engineering and construction. Mechanics of materials; Science: Mathematics: Instruments and machines: Electronic computers. Computer science: Computer software
Website: https://www.nature.com/npjcompumats/

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