| May 08, 2025 |
Atomically thin chromium selenide shows unexpected magnetism, challenging theory and opening new paths for spintronics and advanced electronic devices.
(Nanowerk News) The rules about magnetic order may need to be rewritten. Researchers have discovered that chromium selenide (Cr₂Se₃) – traditionally non-magnetic in bulk form – transforms into a magnetic material when reduced to atomically thin layers. This finding (Nature Communications, “Spin-valley coupling enhanced high-TC ferromagnetism in a non-van der Waals monolayer Cr₂Se₃ on graphene”) contradicts previous theoretical predictions, and opens new possibilities for spintronics applications. This could lead to faster, smaller, and more efficient electronic components for smartphones, data storage, and other essential technologies.
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| In 1966, Mermin and Wagner theoretically predicted that while ferromagnetic order can be stabilized in three-dimensional systems, it cannot be sustained in two-dimensional isotropic systems due to thermal fluctuations (left: 3D, right: 2D). (Image: Takafumi Sato et al.)
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An international research team from Tohoku University, Université de Lorraine (Synchrotron SOLEIL), the National Synchrotron Radiation Research Center (NSRRC), High Energy Accelerator Research Organization, and National Institutes for Quantum Science and Technology successfully grew two-dimensional Cr₂Se₃ thin films on graphene using molecular beam epitaxy. By systematically reducing the thickness from three layers to one layer and analyzing them with high-brightness synchrotron X-rays, the team made a surprising discovery. This finding challenges conventional theoretical predictions that two-dimensional materials cannot maintain magnetic order.
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“When we first observed the ferromagnetic behavior in these ultra-thin films, we were genuinely shocked,” explains Professor Takafumi Sato (WPI-AIMR, Tohoku University), the lead researcher. “Conventional theory told us this shouldn’t happen. What’s even more fascinating is that the thinner we made the films, the stronger the magnetic properties became–completely contrary to what we expected.”
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While three-dimensional Cr₂Se₃ crystals exhibit antiferromagnetism (where magnetic moments cancel each other out), the two-dimensional versions transform into ferromagnetic materials. Even more remarkably, the ferromagnetic transition temperature increases as the films become thinner.
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| (a) Schematic crystal structure of monolayer Cr₂Se₃ grown on a graphene substrate. (b) Photograph of the micro-ARPES system. By irradiating the material surface with ultraviolet light and precisely measuring the energy and momentum of photoemitted electrons via the external photoelectric effect, the electronic structure of the material can be clarified. Furthermore, by focusing the light beam down to the micron scale, it becomes possible to analyze the local electronic structure. (c) Energy band structure of monolayer Cr₂Se₃ determined by micro-ARPES. (d) Valley states populated by electrons transferred from the graphene substrate. (Image: Takafumi Sato et al.)
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Through micro-ARPES analysis of electronic states, researchers identified the mechanism behind this phenomenon: conduction electrons injected from the graphene substrate across the interface into Cr₂Se₃ are the decisive factor enabling high-temperature ferromagnetism in these ultra-thin films.
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Modern electronics primarily utilize the electrical properties of electrons. However, “spintronics” additionally leverages magnetic properties that may offer performance improvements. This discovery significantly expands the possibilities for spintronics applications, potentially leading to more energy-efficient electronic devices. The research team’s next steps will be utilizing the new NanoTerasu synchrotron facility to accelerate their research with higher-resolution analysis.
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