Magnetic skyrmions can be created and annihilated in ferromagnetic multilayers using single femtosecond infrared laser pulses above a material-dependent fluence threshold. From the perspective of applications, optical control of skyrmions offers a route to a faster and, potentially, more energy-efficient new class of information-technology devices. Here, we investigate laser-induced skyrmion generation in two different materials, mapping out the dependence of the process on the applied field and the laser fluence. We observe that sample properties like strength of the Dzyaloshinskii–Moriya interaction and pinning do not considerably influence the initial step of optical creation. In contrast, the number of skyrmions created can be directly and robustly controlled via the applied field and the laser fluence. Based on our findings, we propose concepts for applications, such as all-optical writing and deletion, an ultrafast skyrmion reshuffling device for probabilistic computing, and a combined optical and spin–orbit torque-controlled racetrack.
Magnetic skyrmions
are quasiparticles with nontrivial topology,
envisioned to play a key role in next-generation data technology while
simultaneously attracting fundamental research interest due to their
emerging topological charge. In chiral magnetic multilayers, current-generated
spin–orbit torques or ultrafast laser excitation can be used
to nucleate isolated skyrmions on a picosecond time scale. Both methods,
however, produce randomly arranged skyrmions, which inherently limits
the precision on the location at which the skyrmions are nucleated.
Here, we show that nanopatterning of the anisotropy landscape with
a He+-ion beam creates well-defined skyrmion nucleation
sites, thereby transforming the skyrmion localization into a deterministic
process. This approach allows control of individual skyrmion nucleation
as well as guided skyrmion motion with nanometer-scale precision,
which is pivotal for both future fundamental studies of skyrmion dynamics
and applications.
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