Resolving and Routing Magnetic Polymorphs in a 2D Layered Antiferromagnet

Overview

Journal Nat Mater

Date 2025 Jan 13

PMID 39805959

Authors

Zeyuan Sun

Canyu Hong

Yi Chen

Zhiyuan Sheng

Shuang Wu

Zhanshan Wang

Bokai Liang

Wei-Tao Liu

Zhe Yuan

Yizheng Wu

Qixi Mi

Zhongkai Liu

Jian Shen

Shiwei Wu

Affiliations

Soon will be listed here.

Abstract

Polymorphism, commonly denoting diverse molecular or crystal structures, is crucial in the natural sciences. In van der Waals antiferromagnets, a new type of magnetic polymorphism arises, presenting multiple layer-selective magnetic structures with identical total magnetization. However, resolving and manipulating such magnetic polymorphs remain challenging. Here, phase-resolved magnetic second harmonic generation microscopy is used to elucidate magnetic polymorphism in 2D layered antiferromagnet CrSBr, demonstrating deterministic and layer-selective switching of magnetic polymorphs. Using a nonlinear magneto-optical technique, we unambiguously resolve the polymorphic spin-flip transitions in CrSBr bilayers and tetralayers through both the amplitude and phase of light. Remarkably, the deterministic routing of polymorphic spin-flip transitions originates from a 'layer-sharing' effect, where the transitions are governed by laterally extended layers acting as 'control bits'. We envision that such controllable magnetic polymorphism could be ubiquitous for van der Waals layered antiferromagnets, enabling new designs and constructions of spintronic and opto-spintronic devices for probabilistic computation and neuromorphic engineering.

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