Narrow-linewidth tin-vacancy centers in a diamond waveguide

Abstract

Integrating solid-state quantum emitters with photonic circuits is essential for realizing large-scale quantum photonic processors. Negatively charged tin-vacancy (SnV-) centers in diamond have emerged as promising candidates for quantum emitters because of their excellent optical and spin properties including narrow-linewidth emission and long spin coherence times. SnV- centers need to be incorporated in optical waveguides for efficient on-chip routing of the photons they generate. However, such integration has yet to be realized. In this Letter, we demonstrate the coupling of SnV- centers to a nanophotonic waveguide. We realize this device by leveraging our recently developed shallow ion implantation and growth method for generation of high-quality SnV- centers and the advanced quasi-isotropic diamond fabrication technique. We confirm the compatibility and robustness of these techniques through successful coupling of narrow-linewidth SnV- centers (as narrow as 362 MHz) to the diamond waveguide. Furthermore, we investigate the stability of waveguide-coupled SnV- centers under resonant excitation. Our results are an important step toward SnV--based on-chip spin-photon interfaces, single-photon nonlinearity, and photon-mediated spin interactions.