TY - JOUR
T1 - The role of temperature and drive current in skyrmion dynamics
AU - Litzius, Kai
AU - Leliaert, Jonathan
AU - Bassirian, Pedram
AU - Rodrigues, Davi
AU - Kromin, Sascha
AU - Lemesh, Ivan
AU - Zazvorka, Jakub
AU - Lee, Kyu Joon
AU - Mulkers, Jeroen
AU - Kerber, Nico
AU - Heinze, Daniel
AU - Keil, Niklas
AU - Reeve, Robert M.
AU - Weigand, Markus
AU - Van Waeyenberge, Bartel
AU - Schütz, Gisela
AU - Everschor-Sitte, Karin
AU - Beach, Geoffrey S.D.
AU - Kläui, Mathias
N1 - Publisher Copyright:
© 2020, The Author(s), under exclusive licence to Springer Nature Limited.
PY - 2020/1/1
Y1 - 2020/1/1
N2 - Magnetic skyrmions are topologically stabilized nanoscale spin structures that could be of use in the development of future spintronic devices. When a skyrmion is driven by an electric current it propagates at an angle relative to the flow of current—known as the skyrmion Hall angle (SkHA)—that is a function of the drive current. This drive dependence, as well as thermal effects due to Joule heating, could be used to tailor skyrmion trajectories, but are not well understood. Here we report a study of skyrmion dynamics as a function of temperature and drive amplitude. We find that the skyrmion velocity depends strongly on temperature, while the SkHA does not and instead evolves differently in the low- and high-drive regimes. In particular, the maximum skyrmion velocity in ferromagnetic devices is limited by a mechanism based on skyrmion surface tension and deformation (where the skyrmion transitions into a stripe). Our mechanism provides a complete description of the SkHA in ferromagnetic multilayers across the full range of drive strengths, illustrating that skyrmion trajectories can be engineered for device applications.
AB - Magnetic skyrmions are topologically stabilized nanoscale spin structures that could be of use in the development of future spintronic devices. When a skyrmion is driven by an electric current it propagates at an angle relative to the flow of current—known as the skyrmion Hall angle (SkHA)—that is a function of the drive current. This drive dependence, as well as thermal effects due to Joule heating, could be used to tailor skyrmion trajectories, but are not well understood. Here we report a study of skyrmion dynamics as a function of temperature and drive amplitude. We find that the skyrmion velocity depends strongly on temperature, while the SkHA does not and instead evolves differently in the low- and high-drive regimes. In particular, the maximum skyrmion velocity in ferromagnetic devices is limited by a mechanism based on skyrmion surface tension and deformation (where the skyrmion transitions into a stripe). Our mechanism provides a complete description of the SkHA in ferromagnetic multilayers across the full range of drive strengths, illustrating that skyrmion trajectories can be engineered for device applications.
UR - http://www.scopus.com/inward/record.url?scp=85078336876&partnerID=8YFLogxK
U2 - 10.1038/s41928-019-0359-2
DO - 10.1038/s41928-019-0359-2
M3 - Article
AN - SCOPUS:85078336876
SN - 2520-1131
VL - 3
SP - 30
EP - 36
JO - Nature Electronics
JF - Nature Electronics
IS - 1
ER -