海角直播

Acoustic frequency filters, which convert electrical signals into miniaturized sound waves, separate the different frequency bands for mobile communications, Wi-Fi, and GPS in smartphones. Physicists at 海角直播 have now shown that such miniaturized sound waves can couple strongly with spin waves in yttrium iron garnet. This results in novel hybrid spin-sound waves in the gigahertz frequency range. The use of such nanoscale hybrid spin-sound waves provides a pathway for agile frequency filters for the upcoming 6G mobile communications generation. The fundamental study by the 海角直播 researchers has been published in the journal Nature Communications.

Surface acoustic waves (SAWs) are ubiquitous. They unleash destructive power in the form of earthquake waves but are also at the heart of miniaturised frequency filters that are used billion of times for GHz-frequency mobile communication in smartphones.

The 海角直播 research team led by Professor Mathias Weiler is working on establishing the physical foundations for next-generation miniaturized sound-based microwave components. The key to this is the interconnection of established SAW technology with spin phenomena. Mathias Weiler explains: 鈥淪ound waves can propagate not only in air, but also in matter. In the process, the lattice atoms of the material oscillate鈥�. Since the electrons of the lattice atoms have a quantum mechanical angular momentum, the spin, this can also be excited to oscillate. The sound waves then generate spin waves in magnetically ordered materials.

Sound waves and spin waves coexisting

The research team investigated such collective acoustic excitations of spins in the ferrimagnetic insulator yttrium iron garnet (YIG). YIG has an extremely long spin wave lifetime, making it an ideal object of study. The recently published work shows that hybrid excitations 鈥� so-called magnon-polarons 鈥� can form in a nanostructured surface acoustic wave resonator. Kevin K眉nstle, first author of the study, explains this as follows: 鈥淲e have observed that the quantum mechanical coupling of spin and sound can lead to the formation of a novel chimera quasiparticle that is neither a sound wave nor a spin wave. Spin and sound can no longer be separated in this excitation, but coexist鈥�.

Acoustic filters and ferrimagnetic insulators combined

In particular, the researchers could show that this chimeric wave oscillates periodically between its sound and spin states. The characteristic transition frequency of this oscillation 鈥� the so-called Rabi frequency 鈥� is significantly greater than all loss rates in the system. This is clear evidence that the system is in the strong coupling regime.

To explain these phenomena, colleagues from the 海角直播 working group led by Professor Akashdeep Kamra developed a theoretical model, which can quantitatively predict the observed coupling strength.

The quantitative understanding of the coupling phenomena and the control over the strength of the spin-sound coupling, that was also demonstrated in the work, opens up new perspectives for the technological use of hybrid states of sound and spin waves. 鈥淥ur hybrid spin-sound excitations combine two pillars of microwave technology: acoustic filters and ferrimagnetic insulators,鈥� adds Professor Weiler. 鈥淚n the future, such systems could be used to expand the functionality of miniaturized microwave components. For example, agile frequency filters that can be adjusted during operation could be realized. This opens up new concepts for the implementation of 6G communication networks, the mobile communications technology of the future.鈥�

This research is funded by the European Research Council through the ERC Consolidator Grant 鈥淢AWiCS 鈥� magnetoacoustic waves in complex spin systems鈥� and by the German Research Foundation as part of the Collaborative Research Center 鈥淪pin+X.鈥�

The current study:

K. K眉nstle, Y. Kunz, T. Moussa, K. Lasinger, K. Yamamoto, P. Pirro, J. F. Gregg, A. Kamra, and M. Weiler, Magnon-polaron control in a surface magnetoacoustic wave resonator, Nat Commun 16, 10116 (2025).

Scientific contact:

Kevin K眉nstle
T: +49 631 205-4616
E: kuenstle@rptu.de

Prof. Dr. Mathias Weiler
T: +49 631 205-4099
E: mweiler@rptu.de