Observation of optical vortex generation via magnon-induced Brillouin light scattering

Exploration of physics involving orbital angular momentum (OAM) of light, first recognized in 1992, is essential for deepening our understanding of the interaction between light and matter and that opens up new applications. In systems with rotational symmetry, it is known that OAM can be exchanged between light and matter. One of the most common applications of such a phenomenon is manipulating the optical OAM through the exchange of OAM between light and a nematic liquid crystal-based spatial light modulator (SLM). It is already being used as a tool in many studies related to the optical OAM. However, the operation bandwidth is limited by the response speed 100 Hz of the liquid crystal, which hinders the applications of the optical OAM to spatial division multiplexing, quantum communication, and optical microscopy. The generation of optical vortex beams with the optical OAM in inelastic scattering by elementary excitations with gigahertz-order resonance may solve this problem, although it has not been studied so far. Here, we demonstrate the generation of the optical vortex beams using magnon-induced Brillouin light scattering. We observe scattering rules in the Brillouin light scattering which can be explained by conservation of total angular momentum including spins and orbits with photons and magnons. This work serves as a starting point for research into the interaction between optical vertices and magnons. It opens up devices with the novel mechanism of optical OAM generation together with high operation bandwidth.