Recently, light-matter interaction has been vastly expanded as a control tool for inducing and enhancing many emergent nonequilibrium phenomena. However, conventional schemes for exploring such light-induced phenomena rely on uniform and diffraction-limited free-space optics, which limits the spatial resolution and the efficiency of light-matter interaction. Here, we overcome these challenges using metasurface plasmon polaritons (MPPs) to form a sub-wavelength optical lattice. Specifically, we report a "nonlocal" pump-probe scheme where MPPs are excited to induce a spatially modulated AC Stark shift for excitons in a monolayer of MoSe<sub>2</sub>, several microns away from the illumination spot. We identify nearly two orders of magnitude reduction for the required modulation power compared to the free-space optical illumination counterpart. Moreover, we demonstrate a broadening of the excitons' linewidth as a robust signature of MPP-induced periodic sub-diffraction modulation. Our results will allow exploring power-efficient light-induced lattice phenomena below the diffraction limit in active chip-compatible MPP architectures.
Johannes Scherzer, Lukas Lackner, Bo Han, Borislav Polovnikov, Lukas Husel, Jonas Göser, Zhijie Li, Jens-Christian Drawer, Martin Esmann, Christoph Bennenhei, Falk Eilenberger, Kenji Watanabe, Takashi Taniguchi, Anvar S. Baimuratov, Christian Schneider, Alexander Högele
Armando Genco, Charalambos Louca, Cristina Cruciano, Chiara Trovatello, Sam Randerson, Peter Claronino, Rahul Jayaprakash, Kenji Watanabe, Takashi Taniguchi, David G. Lidzey, Stefano Dal Conte, A. I. Tartakovskii, Giulio Cerullo
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