A recent breakthrough in the control of helimagnetic order promises to reshape the future of spintronic devices and magnetic memory technology. Researchers at the Institute of Science Tokyo have demonstrated a novel method to reversibly reorient the magnetic helix propagation direction in a cubic chiral magnet by manipulating the polarity of an electric current under an applied magnetic field.
Traditional magnetic memory technologies primarily operate by controlling straightforward magnetic configurations in ferromagnets, where all magnetic moments align uniformly. However, helimagnets—characterized by spiral or helical arrangements of magnetic moments—offer richer magnetic textures that can potentially encode information more densely and with greater efficiency. Until now, the ability to switch the orientation of these complex magnetic helices using electric currents remained elusive.
The team, led by Professor Fumitaka Kagawa with graduate student Soju Furuta, focused on the helimagnetic material Co_8.5Zn_8.5Mn_3. Their experimental approach utilized a symmetry-based parameter called the “director” to describe the helix propagation direction, reflecting its headless arrow nature where opposite directions are indistinguishable. This nuanced framework was crucial, as it enabled precise characterization of the magnetic order within the material.
Leveraging in situ Lorentz transmission electron microscopy, the researchers could directly image the dynamic evolution of magnetic structures in response to applied electric currents and magnetic fields. Remarkably, they found that applying a current pulse could induce a 90-degree rotation of the helix propagation vector. Reversing the polarity of the current then restored the original configuration, achieving fully reversible and polarity-selective switching of the helimagnetic order.
Further investigation revealed that the resulting magnetic configuration depends intricately on the relative orientations of the applied current and magnetic field. This finding dovetailed with the team’s theoretical model, which posits that the interplay of current-induced effective fields and magnetic fields selectively stabilizes certain helix orientations. Furuta explains that their results confirm the feasibility of driving reversible reorientation for helices aligned in arbitrary directions, simply by adjusting external field parameters.
This advance pioneers a symmetry-guided paradigm for manipulating complex magnetic textures electrically, transcending the limits of prior ferromagnetic-based control schemes. The controlled switching of helimagnetic states not only deepens fundamental understanding but also broadens the palette of magnetic states available for future information storage technologies.
The implications of this work extend to the development of next-generation spintronic devices that exploit topologically sophisticated magnetic orders for enhanced functionality. By unlocking reversible current-driven control over helimagnetic order, the research team sets the stage for innovative memory architectures with higher density and lower energy consumption.
As the exploration of electrically controlled magnetic materials intensifies, this breakthrough offers a strategic framework to engineer novel spintronic components, potentially revolutionizing how information is stored and manipulated in the quantum era.
Article Title: Reversible reorientation of the helimagnetic q-director in a cubic chiral magnet by electric-current polarity
News Publication Date: 1-Jul-2026
References: DOI: 10.1038/s43246-026-01211-z
Image Credits: Institute of Science Tokyo
Keywords
Helimagnets, Spintronics, Magnetic memory, Electric current control, Magnetic helices, Lorentz transmission electron microscopy, Cubic chiral magnets, Magnetic order reorientation
Tags: Co_8.5Zn_8.5Mn_3 magnetic propertiescubic chiral magnetsdense information encoding in magnetic textureselectric current manipulation in magnetic materialselectric field control of magnetic structureshelimagnetic controlhelimagnetic order reorientationin situ Lorentz microscopymagnetic memory technologyreversible magnetic helix switchingspintronic device innovationsymmetry-based magnetic parameters


