| Literature DB >> 33740371 |
Roméo Juge1, Kaushik Bairagi1, Kumari Gaurav Rana1, Jan Vogel2, Mamour Sall3, Dominique Mailly4, Van Tuong Pham1, Qiang Zhang1, Naveen Sisodia1, Michael Foerster5, Lucia Aballe5, Mohamed Belmeguenai6, Yves Roussigné6, Stéphane Auffret1, Liliana D Buda-Prejbeanu1, Gilles Gaudin1, Dafiné Ravelosona3,4, Olivier Boulle1.
Abstract
Magnetic skyrmions are deemed to be the forerunners of novel spintronic memory and logic devices. While their observation and their current-driven motion at room temperature have been demonstrated, certain issues regarding their nucleation, stability, pinning, and skyrmion Hall effect still need to be overcome to realize functional devices. Here, we demonstrate that focused He+-ion-irradiation can be used to create and guide skyrmions in racetracks. We show that the reduction of the perpendicular magnetic anisotropy and Dzyaloshinskii-Moriya interaction in the track defined by ion-irradiation leads to the formation of stable isolated skyrmions. Current-driven skyrmion motion experiments and simulations reveal that the skyrmions move along the irradiated track, resulting in the suppression of the skyrmion Hall effect, and that the maximum skyrmion velocity can be enhanced by tuning the magnetic properties. These results open up a new path to nucleate and guide magnetic skyrmions in racetrack devices.Entities:
Keywords: current-induced dynamics; ion-irradiation; magnetic patterning; magnetic skyrmions; racetrack; skyrmion Hall effect
Year: 2021 PMID: 33740371 DOI: 10.1021/acs.nanolett.1c00136
Source DB: PubMed Journal: Nano Lett ISSN: 1530-6984 Impact factor: 11.189