he taming of magnetic vortices: A unified theory for skyrmio Source: University of Cologne
Chiral magnetic materials promise a lot of new functionalities with an interesting interplay of electronic and magnetic properties. A team of physicists from Technische Universität München and University of Cologne succeeded in characterizing the electromagnetic properties of insulating, semiconducting and conducting skyrmion-materials and developed a unified theoretical description of their behavior.
Credit: Illustration: Christoph Hohmann / NIM
Magnetic vortex structures, so-called skyrmions, could in future store and process information very efficiently. They could also be the basis for high-frequency components. For the first time, a team of physicists succeeded in characterizing the electromagnetic properties of insulating, semiconducting and conducting skyrmion-materials and developed a unified theoretical description of their behavior. This lays the foundation for future electronic components with purpose-designed properties.
More than six years ago, physicists at the Technische Universität München discovered extremely stable magnetic vortex structures in a metallic alloy of manganese and silicon. Since then, they have driven this technology further together with theoretical physicists from the University of Cologne.
Since magnetic vortices are microscopic and easy to move, computer components may need 10,000 times less electricity than today with this technology and store much larger amounts of data. Recent research results showed that the unique electromagnetic properties of skyrmions could also be used for the construction of efficient and very small microwave receivers and transmitters.
Conductors, semiconductors and insulators
The production of computer chips requires insulating, semiconducting and conducting materials. Today, magnetic vortex structures are available for all these three classes of materials. An important advantage is that these vortices respond easily to alternating fields so that information can be processed at high rates. A team of physicists at the TU München, the University of Cologne and the École Polytechnique Fédérale de Lausanne (Switzerland) has examined the dynamic behavior of the three materials.
With the results of their measurements, the team developed a theoretical description of behavior valid for all three material classes. "With this theory, we have laid an important foundation for further developments," says Professor Dirk Grundler, Chair of Physics of Functional Multilayers at the TU München. "In the future, we will therefore be able to identify materials with the specific properties we need for functional devices."
Extremely compact frequency devices
The typical resonance frequencies of the skyrmions are in the microwave range -- the frequency range of mobile phones, Wi-Fi and many types of microelectronic remote controls. Thanks to the robustness of the magnetic vortices and their ease of excitability, skyrmion-materials could be the basis for highly efficient microwave transmitters and receivers.
While the wavelength of electromagnetic microwaves typically lies in the range of centimeters, the wave lengths of the magnetic spin waves, so-called magnons, are 10,000 times shorter. "In the area of microelectronics, much more compact or even entirely new devices could be developed from magnetic nanomaterials such as the skyrmion-materials," says Grundler.
In addition to the material itself, its shape also significantly influences the electromagnetic properties of the device. Here, too, the researchers' newly developed theory is very useful. It can predict which form produces the best properties for which material.
"Chiral magnetic materials promise a lot of new functionalities with an interesting interplay of electronic and magnetic properties," says Dr. Markus Garst, a physicist at the Institute for Theoretical Physics at the University of Cologne. "But for all applications, it is essential to predict the possibilities and limitations of various materials. We have come a big step closer to achieving this goal."
The work was funded by the European Research Council (ERC Advanced Grant), the Deutsche Forschungsgemeinschaft (TRR 80, SFB 608 and Nanosystems Initiative Munich, NIM) as well as the TUM Graduate School.
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