English

Slow-wave based magnonic diode

Applied Physics 2020-08-26 v1 Mesoscale and Nanoscale Physics

Abstract

Spin waves, the collective excitations of the magnetic order parameter, and magnons, the associated quasiparticles, are envisioned as possible data carriers in future wave-based computing architectures. On the road towards spin-wave computing, the development of a diode-like device capable of transmitting spin waves in only one direction, thus allowing controlled signal routing, is an essential step. Here, we report on the design and experimental realization of a microstructured magnonic diode in a ferromagnetic bilayer system. Effective unidirectional propagation of spin waves is achieved by taking advantage of nonreciprocities produced by dynamic dipolar interactions in transversally magnetized media, which lack symmetry about their horizontal midplane. More specifically, dipolar-induced nonreciprocities are used to engineer the spin-wave dispersion relation of the bilayer system so that the group velocity is reduced to very low values for one direction of propagation, and not for the other, thus producing unidirectional slow spin waves. Brillouin light scattering and propagating spin-wave spectroscopy are used to demonstrate the diode-like behavior of the device, the composition of which was previously optimized through micromagnetic simulations. simulations.

Keywords

Cite

@article{arxiv.1912.09735,
  title  = {Slow-wave based magnonic diode},
  author = {Matías Grassi and Moritz Geilen and Damien Louis and Morteza Mohseni and Thomas Brächer and Michel Hehn and Daniel Stoeffler and Matthieu Bailleul and Philipp Pirro and Yves Henry},
  journal= {arXiv preprint arXiv:1912.09735},
  year   = {2020}
}

Comments

13 pages, 7 figures

R2 v1 2026-06-23T12:52:13.156Z