Terahertz spin-to-charge current conversion in stacks of ferromagnets and the 
transition-metal dichalcogenide NbSe2

Nádvorník, Lukáš; Gueckstock, Oliver; Braun, Lukas; Niu, Chengwang; Graefe, Joachim; Richter, Gunther; Schuetz, Gisela; Takagi, Hidenori; Zeer, Mahmoud; Seifert, Tom S.; Kubaščík, Peter; Pandeya, Avanindra K.; Anane, Abdelmadjid; Yang, Heejun; Bedoya-Pinto, Amilcar; Parkin, Stuart S. P.; Wolf, Martin; Mokrousov, Yuriy; Nakamura, Hiroyuki; Kampfrath, Tobias

doi:10.1002/admi.202201675

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Terahertz spin-to-charge current conversion in stacks of ferromagnets and the transition-metal dichalcogenide NbSe₂

MPG-Autoren

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Pandeya, Avanindra K.
Nano-Systems from Ions, Spins and Electrons, Max Planck Institute of Microstructure Physics, Max Planck Society;

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Bedoya-Pinto, Amilcar
Nano-Systems from Ions, Spins and Electrons, Max Planck Institute of Microstructure Physics, Max Planck Society;

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Parkin, Stuart S. P.
Nano-Systems from Ions, Spins and Electrons, Max Planck Institute of Microstructure Physics, Max Planck Society;

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https://doi.org/10.1002/admi.202201675
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Adv Materials Inter-2022-Nadvornik.pdf
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Zitation

Nádvorník, L., Gueckstock, O., Braun, L., Niu, C., Graefe, J., Richter, G., et al. (2023). Terahertz spin-to-charge current conversion in stacks of ferromagnets and the transition-metal dichalcogenide NbSe₂. Advanced Materials Interfaces, 9(36): 2201675. doi:10.1002/admi.202201675.

Zitierlink: https://hdl.handle.net/21.11116/0000-000B-79AE-A

Zusammenfassung

Transition-metal dichalcogenides (TMDCs) are an aspiring class of materials with unique electronic and optical properties and potential applications in spin-based electronics. Here, terahertz emission spectroscopy is used to study spin-to-charge current conversion (S2C) in the TMDC NbSe₂ in ultra-high-vacuum-grown F|NbSe₂ thin-film stacks, where F is a layer of ferromagnetic Fe or Ni. Ultrafast laser excitation triggers an ultrafast spin current that is converted into an in-plane charge current and, thus, a measurable THz electromagnetic pulse. The THz signal amplitude as a function of the NbSe₂ thickness shows that the measured signals are fully consistent with an ultrafast optically driven injection of an in-plane-polarized spin current into NbSe₂. Modeling of the spin-current dynamics reveals that a sizable fraction of the total S2C originates from the bulk of NbSe₂ with the opposite, negative sign of the spin Hall angle as compared to Pt. By a quantitative comparison of the emitted THz radiation from F|NbSe₂ to F|Pt reference samples and the results of ab initio calculations, it is estimated that the spin Hall angle of NbSe₂ for an in-plane polarized spin current lies between -0.2% and -1.1%, while the THz spin-current relaxation length is of the order of a few nanometers.