Nanobeam Laser Cavities with High Quality-factor and Near-Unity Outcoupling Efficiency

Abstract

Cavities with high quality (Q) factor and small mode-volume are crucial to realize high-performance nanolasers suitable for optical interconnects. In this work, we propose a novel one-dimensional photonic crystal nanobeam cavity design with fins for controlled electrical injection into the active region. An effective optimization algorithm based on first-order perturbation theory of quasinormal modes is implemented and shown to significantly enhance the cavity quality factor. The one-dimensional geometry of the cavity lends itself to unidirectional coupling of the resonant mode into the waveguide by introducing asymmetry of the mirror. The resulting design is shown to achieve high extraction efficiencies (>90\%) while maintaining a high Q-factor (>10 · 103). Through an analysis of the cavity's decay channels, we find that the introduced asymmetry induces unexpected interactions between the cavity's decay channels. Passive InP cavities are fabricated and experimentally characterized, demonstrating record-high quality factors exceeding 170 · 103 for designs without fins and up to 70 · 103 for designs with fins, confirming the efficacy of the optimization method and quality of the fabrication process.