Mode identification of high-quality-factor single-defect nanocavities in quantum dot-embedded photonic crystals

TL;DR

This paper demonstrates the design and experimental realization of high-Q nanocavities in photonic crystals with embedded quantum dots, achieving record Q/V ratios and multiple cavity modes.

Contribution

It introduces a method to optimize nanocavity design for higher Q factors by modulating air hole parameters while maintaining symmetry, and reports the highest Q/V ratio for QD-embedded PC nanocavities.

Findings

Maximum Q of 17,000 achieved experimentally

Q/V ratio of 44,000(n/lambda)^3 reported

Observation of ten cavity modes within the bandgap

Abstract

We investigate the quality (Q) factor and the mode dispersion of single-defect nanocavities based on a triangular-lattice GaAs photonic-crystal (PC) membrane, which contain InAs quantum dots (QDs) as a broadband emitter. To obtain a high Q factor for the dipole mode, we modulate the radii and positions of the air holes surrounding the nanocavity while keeping six-fold symmetry. A maximum Q of 17,000 is experimentally demonstrated with a mode volume of V=0.39(lambda/n)^3. We obtain a Q/V of 44,000(n/lambda)^3, one of the highest values ever reported with QD-embedded PC nanocavities. We also observe ten cavity modes within the first photonic bandgap for the modulated structure. Their dispersion and polarization properties agree well with the numerical results.