Tittle: Topology-Optimized Dielectric Metasurface Cavities for Enhanced Valley Polarized Excitonic Light Emission from WSe₂

Plasmonic cavities have been extensively studied for their ability to localize optical modes via strong confinement by metallic structures, advancing light-matter interactions such as exciton-photon coupling and Purcell enhancement. However, their performance is limited by non-radiative decay. Dielectric cavities offer a promising alternative with significantly lower losses. Photonic inverse design and topology optimization further enable dielectric cavities with sub-diffraction mode volumes and high quality factors (Q), making them ideal for Purcell enhancement and lifetime shortening. This spatial control over Purcell enhancement is crucial for applications in on-chip quantum photonics, nanolasers, and valleytronics.

We leverage topology-optimized silicon metasurface cavities to enhance photon-exciton coupling in few-layer WSe₂, achieving transverse mode sizes of 20-30 nm while minimizing losses. This leads to significant photoluminescence (PL) enhancement and exciton lifetime shortening, consistent with expected Purcell enhancement. Additionally, we observe enhanced valley polarization in WSe₂ due to localized modes, opening opportunities for valleytronic devices and quantum computing. Our design allows nanoscale-precision cavity placement, enabling efficient photonic integration with 2D van der Waals materials like WSe₂ for potential applications.