Ultrafast time-evolution of magnetic chirality probed by circular dichroism in x-ray resonant magnetic scattering in homochiral skyrmionic systems

Noncollinear spin textures in ferromagnetic ultrathin films are attracting a renewed interest fuelled by the discovery of the interfacial Dzyaloshinskii-Moriya (DM) interaction. They are at the origin of complex chiral spin textures such as chiral magnetic domain walls, spin spirals, and magnetic skyrmions. We report here on the ultrafast behavior of chiral domain walls in perpendicularly magnetized asymmetric multilayers after optical pumping probed using circular dichroism in time-resolved x-ray resonant magnetic scattering (XRMS). In addition to the reduction of the magnetization, we report an ultrafast change of the magnetic chirality occurring in the first few picoseconds after optical pumping. Then the XRMS signal, related to the homochiral N\'eel domain wall periodicity is recovered faster that the domain magnetization and subsequently accompanied by a 6 GHz oscillation lasting up to nanosecond time scales. We attribute the short timescale XRMS dichroism reduction in the diffracted intensity to the spin current induced coherent and incoherent torques within the continuously varying spin texture of the domain walls. We argue that the specific demagnetization in the domain walls induces a flow of hot spins from the interior of the domains that distort their homochiral N\'eel shape into transient mixed Bloch-N\'eel-Bloch textures. Time-resolved circular dichroism in XRMS can be a unique tool for studying the time evolution of the type and the chirality of the magnetic phase of any ferroic (magnetic, electric, multiferroic) material. Similar investigations could be profitably extended to other systems showing a non-collinear electric/magnetic ordering such as skyrmion lattices or conical/helical phases stabilized by the DM interaction, as well as more complex systems such as the recently observed antiskyrmion lattices, in metallic or insulating materials.