Coherent Control of Relativistic Electron Dynamics in Plasma Nanophotonics

Femtosecond laser pulses, amplified to ultrahigh intensities, can drive electrons in solids to relativistic energies via collective motion, paving the way for miniaturized particle accelerators and powerful extreme-ultraviolet light sources. However, precisely controlling the space-time properties of these ultra-fast electrons on sub-femtosecond timescales remains a formidable challenge due to the complex nature of interaction at such extreme fields. Here, we present a novel approach to coherently control the local fields on sub-femtosecond timescales at the interface between vacuum and spatially structured plasma generated from a periodic array of dielectric nanopillars. We experimentally demonstrate and theoretically explain that such control of fields enables enhanced acceleration and steering of relativistic electrons in a desired direction. Furthermore, our simulations predict the coherent formation of sub-femtosecond electron bunches from the nanopillars. Our research brings nanophotonics to the realm of strong-field plasma physics and represents the enabling advancement for in-situ control of high-energy particles, paving the way for novel applications in plasma technology.