Formation of Domains Within a Lower-to-Higher Symmetry Structural Transition in CrI

Overview

Journal Inorg Chem

Specialty Chemistry

Date 2023 Dec 29

PMID 38157566

Authors

Petr Dolezal

Marie Kratochvilova

David Hovancik

Vaclav Holy

Vladimir Sechovsky

Jiri Pospisil

Affiliations

Soon will be listed here.

Abstract

CrI represents one of the most important van der Waals systems on the route to understanding 2D magnetic phenomena. Being arranged in a specific layered structure, it also provides a unique opportunity to investigate structural transformations in dimension-confined systems. CrI is dimorphic and possesses a higher symmetry low-temperature phase, which is quite uncommon. It contrasts with vanadium trihalides, which show a higher symmetry high-temperature phase. An explanation of this distinct behavior, together with a large cycle-dependent transition hysteresis, is still an open question. Our low-temperature X-ray diffraction study conducted on CrI single crystals complemented by magnetization and specific heat measurements was focused mainly on specific features of the structural transition during cooling. Our results manifest that the structural transition during cooling relates to the formation of structural domains despite the lower symmetry structure transforming to a higher symmetry one. We propose that these domains could control the size of thermal hysteresis.

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