Active Ferromagnetic Metasurface with Topologically Protected Spin Texture for Spectral Filters

Electromagnetic metasurfaces modulate a material's response to electromagnetic waves by specifically arranged elements with dimensions below the wavelength. They have opened new fields of research, including flat optics and nanophotonics on a chip. Ferromagnetic metasurfaces could become the bu...

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Bibliographic Details
Published inAdvanced functional materials Vol. 32; no. 34
Main Authors Yu, Haiming, Chen, Jilei, Cros, Vincent, Bortolotti, Paolo, Wang, Hanchen, Guo, Chenyang, Brandl, Florian, Heimbach, Florian, Han, Xiufeng, Anane, Abdelmadjid, Grundler, Dirk
Format Journal Article
LanguageEnglish
Published Hoboken Wiley Subscription Services, Inc 01.08.2022
Subjects
Damping
Electromagnetic radiation
Electromagnetic wave filters
Ferromagnetic materials
Insulators
magnetic vortex
Magnons
Materials science
Metasurfaces
Microwave antennas
nanomagnonics
spectral filters
topological protection
Wave propagation
Yttrium-iron garnet
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Summary:Electromagnetic metasurfaces modulate a material's response to electromagnetic waves by specifically arranged elements with dimensions below the wavelength. They have opened new fields of research, including flat optics and nanophotonics on a chip. Ferromagnetic metasurfaces could become the building blocks for manipulation of both microwaves and spin waves (magnons). So far, the functionality of magnonic devices has been limited by high intrinsic damping of the materials employed, suppressing long‐distance spin‐wave propagation. Here ferromagnetic metasurfaces are reported, which are created from periodic arrays of either 15 nm thick Co20Fe60B20, Ni80Fe20 or Co nanodisks on ferrimagnetic yttrium iron garnet (YIG) hosting topologically protected vortex states. This device, a reconfigurable spectral filter, operates in the microwave regime near 0.9 GHz and manipulates long‐distance spin‐wave transmission in thin YIG. An efficiency of 98.5% is demonstrated, with the metasurface covering only 15% of the microwave antenna. This first demonstration of a ferromagnetic metasurface opens unprecedented possibilities for on‐chip control of microwaves in low‐damping ferrimagnetic insulators. Metasurfaces provide control over electromagnetic waves, which goes beyond natural materials. They consist of precisely engineered hybrid materials. By the combination of ferromagnetic nanodisks hosting topologically protected vortex states with a ferrimagnetic thin film, a metasurface is created which shows magnetically switchable microwave filtering and on‐chip manipulation of microwaves at ultrasmall length scale.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202203466