Ultrafast Microscopy of a Plasmonic Spin Skyrmion

We present an ultrafast microscopy imaging experiment and a general analytical description of a new quasiparticle composed of plasmonic Skyrmion-like spin texture at the core of a surface plasmon polariton (SPP) vortex. The illumination of a circular coupling structure milled in an Ag film by circularly polarized light (CPL) couples its spin angular momentum (SAM) into orbital angular momentum (OAM) of SPPs launching them to form a plasmonic vortex. The coupling of the cycloidal motion of the SPP polarization at the 2D interface, with their orbital swirl at the vortex core causes the plasmonic field to generate 3D SAM pseudovectors, whose topological texture has integer Skyrmion number and is homotopic to a twisted magnetic Skyrmion quasiparticle with the boundary defined by an optical L-line singularity contour. An analytical description finds that the dielectric discontinuity at the Ag/vacuum interface supports on each side entwined twisted Skyrmion pairs that are characterized by stable topological textures with opposite Skyrmion numbers. The SAM texture of the Skyrmion pair within the primary vortex ring corresponds to a monopole-hedgehog type SAM texture, with a SAM singularity at the vortex core. Interferometric time-resolved two-photon photoemission electron microscopy (ITR-2P-PEEM) imaging of the nanofemto spatiotemporal evolution of the SPP fields and simulation by an analytical model, establish the twisted topological plasmonic SAM Skyrmion quasiparticle at the vortex core. The SAM textures can probe and simulate topological responses in trivial and topological materials that can be coupled in the near-field of the SPP vortex. The theory anticipates different field structures and the accompanying topological spin textures that construct single Skyrmion and meron-like quasiparticles as well as their arrays.