Free-standing circular Bragg gratings enabling efficient GaAs quantum dot entangled photon pair sources

Abstract

Deterministic and bright quantum light sources based on scalable semiconductor technologies are a crucial building block for future quantum communication networks. While circular Bragg gratings (CBGs) are highly effective for extracting light from solid-state quantum emitters, conventional architectures rely on complex multi-layer processing or flip-chip bonding, which introduce detrimental strain and limit scalability. Here, we present a fabrication-minimal approach to realize monolithic, free-standing CBG cavities with deterministically positioned single GaAs quantum dots (QDs). By utilizing aspect-ratio-dependent etching (ARDE) in a single-step top-down process, we achieve the necessary vertical structural asymmetry for directional emission without requiring bottom reflectors. Finite-difference time-domain (FDTD) simulations validate this geometry, predicting free-space extraction efficiencies up to 68 \, \% and coupling efficiencies of 40 \, \% into a lensed single-mode fiber (NA = 0.6). Experimentally, the deterministically coupled QD-CBG devices yield a photoluminescence intensity enhancement of up to × 700 compared to unprocessed planar QDs, reaching integrated count rates of 45 \, MHz. Furthermore, the suspended membrane architecture effectively relaxes residual strain, significantly reducing the average exciton fine-structure splitting from 7.3 \, μ eV in planar QDs to 1.3 \, μ eV in the CBGs. Interferometric measurements confirm that the fabrication process preserves the optical quality of the emitters, with average coherence times of 70 \, ps. By bridging optimized FDTD design with precise nanofabrication and robust optical performance, these results establish free-standing GaAs CBGs as a highly scalable platform for bright and coherent entangled photon pair sources.