This strange magnetism could power tomorrow’s AI
A newly revealed magnetic state in ruthenium dioxide could be the secret to faster, denser, and more reliable memory chips.
- Date:
- December 26, 2025
- Source:
- National Institute for Materials Science, Japan
- Summary:
- Scientists in Japan have confirmed that ultra-thin films of ruthenium dioxide belong to a newly recognized and powerful class of magnetic materials called altermagnets. These materials combine the best of two magnetic worlds: they’re stable against interference yet still allow fast, electrical readout—an ideal mix for future memory technology.
- Share:
An international research team from NIMS, The University of Tokyo, Kyoto Institute of Technology, and Tohoku University has shown that ultra-thin films of ruthenium dioxide (RuO2) display altermagnetism. This property defines what scientists now recognize as a third fundamental category of magnetic materials. Altermagnets are drawing growing interest because they could overcome key limitations of today's magnetic memory technologies and enable faster, more compact data storage.
The researchers also found that the performance of RuO2 thin films can be improved by carefully controlling how their crystal structure is oriented during fabrication. Their findings were published in Nature Communications.
Why Scientists Are Searching for New Magnetic Materials
Ruthenium dioxide (RuO2) has long been considered a promising candidate for altermagnetism, a recently proposed form of magnetism that differs from conventional types. Standard ferromagnetic materials used in memory devices allow data to be written easily using external magnetic fields. However, they are vulnerable to interference from stray magnetic fields, which can cause errors and limit how densely information can be stored.
Antiferromagnetic materials offer much better resistance to external magnetic disturbances. The challenge is that their internal magnetic spins cancel each other out, making it difficult to read stored information using electrical signals. As a result, scientists have been searching for materials that combine magnetic stability with electrical readability and, ideally, the ability to be rewritten. While altermagnets promise this balance, experimental results for RuO2 have varied widely around the world. Progress has also been slowed by the difficulty of producing high-quality thin films with a consistent crystallographic orientation.
How the Team Verified Altermagnetism
The research team overcame these obstacles by successfully creating RuO2 thin films with a single crystallographic orientation on sapphire substrates. By carefully choosing the substrate and fine-tuning the growth conditions, they were able to control how the crystal structure formed.
Using X-ray magnetic linear dichroism, the researchers mapped the spin arrangement and magnetic order in the films, confirming that the overall magnetization (N-S poles) cancels out. They also detected spin-split magnetoresistance, meaning the electrical resistance changes depending on the spin direction. This effect provided electrical evidence of a spin-split electronic structure.
The experimental results matched first-principles calculations of magneto-crystalline anisotropy, confirming that the RuO2 thin films truly exhibit altermagnetism (see Figure). Together, these findings strongly support the potential of RuO2 thin films for next-generation high-speed, high-density magnetic memory devices.
Toward Faster and More Efficient Memory Devices
Building on this work, the team plans to develop advanced magnetic memory technologies based on RuO2 thin films. These devices could support faster and more energy-efficient information processing by taking advantage of the natural speed and density offered by altermagnetic materials.
The synchrotron-based magnetic analysis methods established during the study are also expected to help researchers identify and study other altermagnetic materials. This approach could accelerate progress in spintronics and open new pathways for future electronic devices.
Research Team and Funding
This project was conducted by a research group led by Zhenchao Wen (Senior Researcher, Spintronics Group (SG), Research Center for Magnetic and Spintronic Materials (CMSM), NIMS), Cong He (Postdoctoral Researcher, SG, CMSM, NIMS at the time of the research), Hiroaki Sukegawa (Group Leader, SG, CMSM, NIMS), Seiji Mitani (Managing Researcher, SG, CMSM, NIMS), Tadakatsu Ohkubo (Deputy Director, CMSM, NIMS), Jun Okabayashi (Associate Professor, School of Science, The University of Tokyo), Yoshio Miura (Professor, Kyoto Institute of Technology), and Takeshi Seki (Professor, Tohoku University).
The work was supported by the JSPS Grants-in-Aid for Scientific Research (grant numbers: 22H04966, 24H00408), the MEXT Initiative to Establish Next-Generation Novel Integrated Circuits Centers (X-NICS) (grant number: JPJ011438), the GIMRT Program of the Institute for Materials Research, Tohoku University, and the Cooperative Research Projects of the Research Institute of Electrical Communication, Tohoku University.
The study was published online in Nature Communications on September 24, 2025.
Story Source:
Materials provided by National Institute for Materials Science, Japan. Note: Content may be edited for style and length.
Journal Reference:
- Cong He, Zhenchao Wen, Jun Okabayashi, Yoshio Miura, Tianyi Ma, Tadakatsu Ohkubo, Takeshi Seki, Hiroaki Sukegawa, Seiji Mitani. Evidence for single variant in altermagnetic RuO2(101) thin films. Nature Communications, 2025; 16 (1) DOI: 10.1038/s41467-025-63344-y
Cite This Page: