Realization of magnetic skyrmions in thin films at ambient conditions

Magnetic skyrmions present interesting physics due to their topological nature and hold significant promise for future informational technologies. A key barrier to realizing skyrmion devices has been stabilizing these spin structures in ambient conditions. I will discuss how we exploited the tunable magnetic properties of amorphous Fe/Gd films to realize, for the first time, skyrmion lattices in continuous amorphous thin-films, stable at room temperature and zero magnetic field. These Bloch-type skyrmions are stabilized by dipolar interactions rather than traditional Dzyaloshinskii-Moriya interactions. Small angle neutron scattering was used in combination with soft x-ray microscopy providing a unique, multi-scale probe of the local and long-range order of these structures. Key to this work was to prepare an artificial stripe phase, which evolves into the hexagonally ordered skyrmion lattice structure under increasing magnetic field. These results identify a pathway to engineer controllable skyrmion phases in thin film geometries which are stable at ambient conditions.