Phoebe Tengdin1,Benoit Truc1,Alexey Sapozhnik1,Simone Gargiulo1,Ivan Madan1,Thomas Schoenenberger1,Priya Baral1,Ping Che1,Arnaud Magrez1,Dirk Grundler1,Henrik Rønnow1,Thomas LaGrange1,Fabrizio Carbone1
École polytechnique fédérale de Lausanne1
Phoebe Tengdin1,Benoit Truc1,Alexey Sapozhnik1,Simone Gargiulo1,Ivan Madan1,Thomas Schoenenberger1,Priya Baral1,Ping Che1,Arnaud Magrez1,Dirk Grundler1,Henrik Rønnow1,Thomas LaGrange1,Fabrizio Carbone1
École polytechnique fédérale de Lausanne1
Control of topological magnetic textures has attracted intense interest due to the potential applications for these structures in spintronic devices. Recent advances in electron microscopy have enabled imaging of individual skyrmions, however the full understanding of their ultrafast dynamics has remained inaccessible. Here we show via <i>cryo</i>- Lorentz microscopy that a single circularly polarized femtosecond laser pulse can induce controlled rotation of a skyrmion crystal. Pulses of light with an energy below the bandgap of the Mott insulator Cu<sub>2</sub>OSeO<sub>3</sub> drive spin currents whose direction and strength determine the direction and degree of the skyrmion crystal rotation. Thermodynamic calculations confirm that the rotation dynamics triggered take place on a timescale more than six orders of magnitude faster than previously measured. This direct manipulation of topological order via laser pulses can be used to engineer spin-based logical devices on much faster timescales than available methods.