Magnetically Confined Surface and Bulk Excitons in a Layered Antiferromagnet

Overview

Journal Nat Mater

Date 2025 Feb 19

PMID 39972108

Authors

Yinming Shao

Florian Dirnberger

Siyuan Qiu

Swagata Acharya

Sophia Terres

Evan J Telford

Dimitar Pashov

Brian S Y Kim

Francesco L Ruta

Daniel G Chica

Avalon H Dismukes

Michael E Ziebel

Yiping Wang

Jeongheon Choe

Youn Jue Bae

Andrew J Millis

Mikhail I Katsnelson

Kseniia Mosina

Zdenek Sofer

Rupert Huber

Xiaoyang Zhu

Xavier Roy

Mark van Schilfgaarde

Alexey Chernikov

D N Basov

Affiliations

Soon will be listed here.

Abstract

The discovery of two-dimensional van der Waals magnets has greatly expanded our ability to create and control nanoscale quantum phases. A unique capability emerges when a two-dimensional magnet is also a semiconductor that features tightly bound excitons with large oscillator strengths that fundamentally determine the optical response and are tunable with magnetic fields. Here we report a previously unidentified type of optical excitation-a magnetic surface exciton-enabled by the antiferromagnetic spin correlations that confine excitons to the surface of CrSBr. Magnetic surface excitons exhibit stronger Coulomb attraction, leading to a higher binding energy than excitons confined in bulk layers, and profoundly alter the optical response of few-layer crystals. Distinct magnetic confinement of surface and bulk excitons is established by layer- and temperature-dependent exciton reflection spectroscopy and corroborated by ab initio many-body perturbation theory calculations. By quenching interlayer excitonic interactions, the antiferromagnetic order of CrSBr strictly confines the bound electron-hole pairs within the same layer, regardless of the total number of layers. Our work unveils unique confined excitons in a layered antiferromagnet, highlighting magnetic interactions as a vital approach for nanoscale quantum confinement, from few layers to the bulk limit.

Citing Articles

Magnetic order as a tuning knob for Coulomb correlation.

Duan J, Zhou Y Nat Mater. 2025; 24(3):332-333.

PMID: 39972107 DOI: 10.1038/s41563-025-02122-z.

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