Publikation: Separating Terahertz Spin and Charge Contributions from Ultrathin Antiferromagnetic Heterostructures
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2025
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European Union (EU): 861300
European Union (EU): 101054664
European Union (EU): 101054664
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Physical Review Letters. American Physical Society (APS). 2025, 135(7), 076702. ISSN 0031-9007. eISSN 1079-7114. Verfügbar unter: doi: 10.1103/76xj-j9qr
Zusammenfassung
Femtosecond laser excitation of nanometer thin heterostructures comprising a heavy metal and a magnetically ordered material is known to result in the emission of terahertz radiation. However, the nature of the emitted radiation from heavy metal/antiferromagnet heterostructures has sparked debates and controversies in the literature. Here, we unambiguously separate spin and charge contributions from Pt/NiO heterostructures by introducing an unprecedented methodology combining high external magnetic fields with a symmetry analysis of the emitted terahertz polarization. We observe two distinct mechanisms of terahertz emission, which we identify as optical difference frequency generation and ultrafast laser-induced quenching of the magnetization. We emphasize the absence of spin transport effects and signatures of coherent magnons. Overall, our Letter provides a general experimental methodology to separate spin and charge contributions to the laser-induced terahertz emission from heterostructures comprising a magnetically ordered material, thus holding great potential for advancing terahertz spintronics and establishing terahertz orbitronics.
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METZGER, Thomas W. J., Peter FISCHER, Takashi KIKKAWA, Eiji SAITOH, Alexey V. KIMEL, Davide BOSSINI, 2025. Separating Terahertz Spin and Charge Contributions from Ultrathin Antiferromagnetic Heterostructures. In: Physical Review Letters. American Physical Society (APS). 2025, 135(7), 076702. ISSN 0031-9007. eISSN 1079-7114. Verfügbar unter: doi: 10.1103/76xj-j9qrBibTex
@article{Metzger2025-08-12Separ-74446,
title={Separating Terahertz Spin and Charge Contributions from Ultrathin Antiferromagnetic Heterostructures},
year={2025},
doi={10.1103/76xj-j9qr},
number={7},
volume={135},
issn={0031-9007},
journal={Physical Review Letters},
author={Metzger, Thomas W. J. and Fischer, Peter and Kikkawa, Takashi and Saitoh, Eiji and Kimel, Alexey V. and Bossini, Davide},
note={Article Number: 076702}
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<dcterms:abstract>Femtosecond laser excitation of nanometer thin heterostructures comprising a heavy metal and a magnetically ordered material is known to result in the emission of terahertz radiation. However, the nature of the emitted radiation from heavy metal/antiferromagnet heterostructures has sparked debates and controversies in the literature. Here, we unambiguously separate spin and charge contributions from Pt/NiO heterostructures by introducing an unprecedented methodology combining high external magnetic fields with a symmetry analysis of the emitted terahertz polarization. We observe two distinct mechanisms of terahertz emission, which we identify as optical difference frequency generation and ultrafast laser-induced quenching of the magnetization. We emphasize the absence of spin transport effects and signatures of coherent magnons. Overall, our Letter provides a general experimental methodology to separate spin and charge contributions to the laser-induced terahertz emission from heterostructures comprising a magnetically ordered material, thus holding great potential for advancing terahertz spintronics and establishing terahertz orbitronics.</dcterms:abstract>
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