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Light-Induced Reorientation Transition in an Antiferromagnetic Semiconductoropen access

Authors
Fichera, Bryan T.Lv, BaiqingMorey, KarnaShen, ZongqiLee, ChangminDonoway, ElizabethLiebman-Peláez, AlexKogar, AnshulKurumaji, TakashiRodriguez-Vega, MartinDel Toro, Rodrigo Humberto AguileraArruabarrena, MikelIlyas, BatyrLuo, TianchuangMüller, PeterLeonardo, AritzAyuela, AndresFiete, Gregory A.Checkelsky, Joseph G.Orenstein, JosephGedik, Nuh
Issue Date
Feb-2025
Publisher
American Physical Society
Citation
Physical Review X, v.15, no.1, pp 1 - 10
Pages
10
Indexed
SCIE
SCOPUS
Journal Title
Physical Review X
Volume
15
Number
1
Start Page
1
End Page
10
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/210629
DOI
10.1103/PhysRevX.15.011044
ISSN
2160-3308
2160-3308
Abstract
Because of the lack of a net magnetic moment, antiferromagnets possess a unique robustness to external magnetic fields and are thus predicted to play an important role in future magnetic technologies. However, this robustness also makes them quite difficult to control, and the development of novel methods to manipulate these systems with external stimuli is a fundamental goal of antiferromagnetic spintronics. In this work, we report evidence for a metastable reorientation of the order parameter in an antiferromagnetic semiconductor triggered by an ultrafast quench of the equilibrium order via photoexcitation above the band gap. The metastable state forms less than 10 ps after the excitation pulse, and persists for longer than 150 ps before decaying to the ground state via thermal fluctuations. Importantly, this transition cannot be induced thermodynamically, and requires the system to be driven out of equilibrium. Broadly speaking, this phenomenology is ultimately the result of large magnetoelastic coupling in combination with a relatively low symmetry of the magnetic ground state. Since neither of these properties are particularly uncommon in magnetic materials, the observations presented here imply a generic path toward novel device technology enabled by ultrafast dynamics in antiferromagnets.
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