Litcius/Paper detail

Generation, transmission, and conversion of orbital torque by an antiferromagnetic insulator

Shilei Ding, Paul Noël, Gunasheel Kauwtilyaa Krishnaswamy, Niccolò Davitti, Giacomo Sala, Marzia Fantauzzi, Antonella Rossi, Pietro Gambardella

2025Nature Communications6 citationsDOIOpen Access PDF

Abstract

Abstract Electrical control of magnetization in nanoscale devices can be significantly improved through the efficient generation of orbital currents and their conversion into spin currents. In nonmagnetic/ferromagnetic bilayers, this conversion produces a torque on the magnetization, enabling magnetization switching and dynamic manipulation. While previous studies focus on metallic ferromagnets, we demonstrate a large orbital torque and enhanced orbital-to-spin conversion by an antiferromagnetic insulating CoO layer. Measurements in CuO x /CoO/Co trilayers show that inserting CoO reverses the torque’s sign and triples its magnitude compared to CuO x /Co. This behaviour stems from the inverted oxygen gradient at the CuO x /CoO interface and CoO’s high orbital multiplicity, which favours the transmission of orbital momenta and efficient orbital-to-spin conversion. At low temperatures, the onset of antiferromagnetic order induces a further many-fold increase of the torque, which we attribute to the efficient excitation and propagation of spin-orbit excitons induced by magnetic coupling. Comparative measurements of CuO x /NiO/Co and CuO x /MnO/Co trilayers show that the torque efficiency scales with the orbital momentum of the Co 2+ , Ni 2+ , and Mn 2+ ions in the antiferromagnet. These results reveal that antiferromagnetic insulators like CoO provide highly effective orbital-to-spin transduction, combining orbital torque and exchange bias functionalities to improve the performance of spintronic devices.

Topics & Concepts

AntiferromagnetismSpintronicsCondensed matter physicsMagnetizationMaterials scienceMagnetic momentTorqueMagnetization dynamicsEnergy conversion efficiencyAngular momentumOrbital magnetizationPhysicsExcitationSpin (aerodynamics)Insulator (electricity)Orbital overlapMagnetic properties of thin filmsZnO doping and propertiesCopper-based nanomaterials and applications