📝 SummarXiv

Abstract

Topological photonic crystals (TPhCs) are the photonic analogs of topological insulators, inspired by the quantum Hall effect and its variants, including the integer, spin, and valley Hall effects. Among these, valley-hall photonic crystals (VPhCs) achieve topological protection by breaking inversion symmetry, making them closely related to valleytronics. Like other TPhCs, VPhCs enable robust, backscattering-free light propagation, even in the presence of structural imperfections, sharp bends, or defects. In this study, we introduce a VPhC design that demonstrates exceptional resilience in guiding light through both linear and \(\Omega\)-shaped waveguides, even under significant structural disorder. Additionally, efficient light confinement is demonstrated within a hexagonal resonant cavity, further underscoring the versatility of the platform. On this basis, a VPhC-based biosensor is proposed, designed to achieve high sensitivity and a strong quality factor, thereby enabling carcinoma cell detection. The work demonstrates that the sensor achieves a maximum quality factor of 285,338 and a maximum sensitivity of 24,300 nm/RIU. This work holds significant promise for advancing medical and clinical diagnostics, paving the way for innovative applications in healthcare.