Two-dimensional heterostructure quasi-BIC photonic crystal surface-emitting laser with low divergence

High beam quality, large-area output, and small footprint are significant pursuing goals for vertical-cavity surface-emitting lasers (VCSELs), which impose strict requirements on tight light confinements with minimized radiation losses. To achieve this, bound states in the continuum (BICs) have been demonstrated as an effective way of trapping light. Here, we combine BICs and photonic bandgaps to realize a quasi-BIC single-mode photonic crystal (PhC) laser on a colloidal quantum dots (CQDs)/silicon oxide (SiO2) hybrid integrated platform. The PhC cavity is a defect-free hexagonal heterostructure with three regions, and the thin CQDs film is embedded within the SiO2 nanopillar planar array as both an optical gain material and a backbone for the PhC. The mode gaps between different regions provide the lateral confinement while the quasi-BICs near the Gamma-point generate the small-divergence vertical radiation coupling, resulting in a well-defined emission concentrating within +/- 1.85 degrees of the normal surface direction and an optical pumping energy density threshold of 216.75 mu J/cm(2). Our results demonstrate the design flexibility and versatility of the quasi-BIC laser even with a low contrast of a refractive index between the PhC slab and the substrate, which has potential applications in cavity quantum electrodynamics, nonlinear optics, and integrated photonics.

Automated summary

We have successfully realized a quasi-bound state in the continuum (BIC) single-mode photonic crystal (PhC) laser based on a colloidal quantum dots (CQDs)/silicon oxide (SiO2) hybrid platform. By combining BICs and photonic bandgaps, we achieved strong light confinement with minimized radiation losses. The quasi-BIC laser exhibits well-defined emission within a small divergence angle and low optical pumping energy density threshold. It has potential applications in various fields including cavity quantum electrodynamics, nonlinear optics, and integrated photonics.