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. 2025 Jun;642(8066):64-70.
doi: 10.1038/s41586-025-09034-7. Epub 2025 May 28.

Electrical switching of a p-wave magnet

Qian Song  1   2 Srdjan Stavrić  3   4 Paolo Barone  5 Andrea Droghetti  3   6 Daniil S Antonenko  7 Jörn W F Venderbos  8 Connor A Occhialini  9 Batyr Ilyas  9 Emre Ergeçen  9 Nuh Gedik  9 Sang-Wook Cheong  10 Rafael M Fernandes  11   12 Silvia Picozzi  3   13 Riccardo Comin  14
Affiliations

Electrical switching of a p-wave magnet

Qian Song et al. Nature. 2025 Jun.

Abstract

Magnetic states with zero magnetization but non-relativistic spin splitting are outstanding candidates for the next generation of spintronic devices. Their electronvolt (eV)-scale spin splitting, ultrafast spin dynamics and nearly vanishing stray fields make them particularly promising for several applications1,2. A variety of such magnetic states with non-trivial spin textures have been identified recently, including even-parity d-wave, g-wave or i-wave altermagnets and odd-parity p-wave magnets3-7. Achieving voltage-based control of the non-uniform spin polarization of these magnetic states is of great interest for realizing energy-efficient and compact devices for information storage and processing8,9. Spin-spiral type II multiferroics are optimal candidates for such voltage-based control, as they exhibit an inversion-symmetry-breaking magnetic order that directly induces ferroelectric polarization, allowing for symmetry-protected cross-control between spin chirality and polar order10-14. Here we combine photocurrent measurements, first-principles calculations and group-theory analysis to provide direct evidence that the spin polarization of the spin-spiral type II multiferroic NiI2 exhibits odd-parity character connected to the spiral chirality. The symmetry-protected coupling between chirality and polar order enables electrical control of a primarily non-relativistic spin polarization. Our findings represent an observation of p-wave magnetism in a spin-spiral type II multiferroic, which may lead to the development of voltage-based switching of non-relativistic spin polarization in compensated magnets.

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Conflict of interest statement

Competing interests: The authors declare no competing interests.

References

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