Oct 05, 2022 |
(Nanowerk News) For about ten years, magnetic skyrmions – particle-like, stable magnetic whirls that can form in certain materials and possess fascinating properties – have been a focus of research: electrically easily controlled and only a few nanometers in size, they are suitable for future applications in spin electronics, quantum computers or neuromorphic chips. These magnetic whirls were first found in regular lattices, so-called skyrmion lattices, and later individual skyrmions were also observed at the University of Hamburg.
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Researchers from Kiel University and the University of Hamburg have now discovered a new class of spontaneously occurring magnetic lattices. They are related to skyrmion lattices, but their “atomic bar magnets” on the nanometer scale are oriented differently. A fundamental understanding of how such complex spin structures form, how they are arranged and remain stable is also needed for future applications.
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The results are published in Nature Communications (“Nano-scale collinear multi-Q states driven by higher-order interactions”).
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The image shows the different orientation of atomic bar magnets of an iron film: In a magnetic mosaic lattice (above), they are oriented in groups either upwards (purple) or downwards (white). In the skyrmion lattice (below), they point in all directions. (Image: André Kubetzka)
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Quantum mechanical interactions
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Attaching magnets to a refrigerator or reading data from a hard drive is only possible because of a quantum mechanical exchange interaction between the atomic bar magnets on the microscopic scale. This interaction, discovered by Werner Heisenberg in 1926, explains not only the parallel alignment of atomic bar magnets in ferromagnets, but also the occurrence of other magnetic configurations, such as antiferromagnets.
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Today many other magnetic interactions are known, which has led to a variety of possible magnetic states and new research questions. This is also important for skyrmion lattices. Here the atomic bar magnets show in all spatial directions, which is only possible due to the competition of different interactions.
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“In our measurements, we found a hexagonal arrangement of magnetic contrasts, and at first we thought that was also a skyrmion lattice. Only later did it become clear that it could be a nanoscale magnetic mosaic,” says PD Dr. Kirsten von Bergmann.
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With her team from the University of Hamburg, she experimentally studied thin metallic films of iron and rhodium using spin-polarized scanning tunneling microscopy. This allows magnetic structures to be imaged down to the atomic scale. The observed magnetic lattices occurred spontaneously as in a ferromagnet, i.e., without an applied magnetic field.
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“With a magnetic field, we can invert the mosaic lattices, because the opposing spins only partially compensate for each other,” explains Dr. André Kubetzka, also from the University of Hamburg.
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A measurement using spin-polarised scanning tunnelling microscopy makes the hexagonal arrangement in the magnetic mosaic lattice visible on the nanoscale. Due to a twist on the atomic lattice, two rotational domains appear deviating by about 13°. (Image: André Kubetzka)
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Surprising: Magnetically different alignment
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Based on these measurements, the group of Prof. Dr. Stefan Heinze (Kiel University) performed quantum mechanical calculations on the supercomputers of the North German High Performance Computing Network (HLRN). They show that in the investigated iron films the tilting of the atomic bar magnets in a lattice of magnetic vortices, i.e. in all spatial directions, is very unfavorable. Instead, a nearly parallel or antiparallel alignment of neighboring atomic bar magnets is favored.
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“This result completely surprised us. A lattice of skyrmions was thus no longer an option to explain the experimental observations,” says Mara Gutzeit, doctoral researcher and first author of the study. The development of an atomistic spin model made clear that it must be a novel class of magnetic lattices, which the researchers called “mosaic lattices”. “We found out that these mosaic-like magnetic structures are caused by higher-order exchange terms, predicted only a few years ago,” says Dr. Soumyajyoti Haldar from the group of Kiel.
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“The study impressively shows how diverse spin structures can be and that a close collaboration between experimentally and theoretically working research groups can be really helpful for their understanding. In this field a few more surprises can be expected in the future,” states Professor Stefan Heinze.
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About spin electronics
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In addition to the charge of the electrons, spin electronics also uses their so-called spin. This electron spin is a quantum mechanical property and can be understood in simplified terms as the rotation of the electrons around their own axis. This is linked to a magnetic moment that leads to the formation of “atomic bar magnets” (atomic spins) in magnetic materials. They are suitable for processing and storing information. Through targeted electrical manipulation, it would be possible to create faster, more energy-saving and more powerful components for information technology.
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