The frequency difference between two oppositely propagating spin waves can be used to probe several interesting magnetic properties, such as the Dzyaloshinkii-Moriya interaction (DMI). Propagating spin wave spectroscopy is a technique that is very sensitive to this frequency difference. Here we show several elements that are important to optimize devices for such a measurement. We demonstrate that for wide magnetic strips there is a need for de-embedding. Additionally, for these wide strips there is a large parasitic antenna-antenna coupling that obfuscates any spin wave transmission signal, which is remedied by moving to smaller strips. The conventional antenna design excites spin waves with two different wave vectors. As the magnetic layers become thinner, the resulting resonances move closer together and become very difficult to disentangle. In the last part we therefore propose and verify a new antenna design that excites spin waves with only one wave vector. We suggest to use this antenna design to measure the DMI in thin magnetic layers.
@article{arxiv.1901.11108,
title = {Optimizing propagating spin wave spectroscopy},
author = {Juriaan Lucassen and Casper F. Schippers and Luuk Rutten and Rembert A. Duine and Henk J. M. Swagten and Bert Koopmans and Reinoud Lavrijsen},
journal= {arXiv preprint arXiv:1901.11108},
year = {2019}
}