Freestanding and positionable microwave-antenna device for magneto-optical spectroscopy experiments

Autor: Hache, T., Vaňatka, M., Flajšman, L., Weinhold, T., Hula, T., Ciubotariu, O., Albrecht, M., Arkook, B., Barsukov, I., Fallarino, L., Hellwig, O., Faßbender, J., Urbánek, M., Schultheiß, H.
Jazyk: angličtina
Rok vydání: 2020
Předmět:
Zdroj: arXiv:1911.11517 [physics.app-ph]: https://arxiv.org/abs/1911.11517
Physical Review Applied 13(2020)5, 054009
DPG-Frühjahrstagung der Sektion Kondensierte Materie, 31.03.-05.04.2019, Universität Regensburg, Deutschland
Popis: Modern spectroscopic techniques for the investigation of magnetization dynamics in micro- and nano- structures or thin films use mostly microwave antennas which are directly fabricated on the sample by means of electron-beam-lithography (EBL). Following this approach, every magnetic structure on the sample needs its own antenna, resulting in additional EBL steps and layer deposition processes. We demonstrate a new device for magnetization excitation that is suitable for optical and non-optical spectroscopic techniques. By patterning the antenna on a separated flexible glass cantilever and insulating it electrically, we solved the be- fore mentioned issues. Since we use flexible transparent glass as a substrate, optical spectroscopic techniques like Brillouin-light-scattering microscopy (μBLS), time resolved magneto-optical Kerr effect measurements (TRMOKE) or optical detected magnetic resonance (ODMR) measurements can be performed at visible laser wavelengths. As the antenna is detached from the sample it can be freely positioned in all three dimensions to get access to all desired magnetic sample structures, while being brought in close contact with the sample for an effective excitation. We show the functionality of these antennas using μBLS. We compare with thermally excited magnons to show the enhancement of the signal by a factor of about 400 demonstrating the high impact of the magnetization excitation by the antenna. Moreover, we show the possibility to characterize yttrium iron garnet thin films by doing optical ferromagnetic resonance (FMR) experiments allowing for the characterization of magnetic properties spatially resolved. Additionally, we show the spatial excitation profile of the antenna by measuring the magnetization dynamics in two dimensions. Furthermore, injection-locking of spin Hall nano-oscillators could be shown.
Databáze: OpenAIRE