Superradiance Enhanced Light-Matter Interaction in Spatially Ordered Shape and Volume Controlled Single Quantum Dots: Enabling On-Chip Photonic Networks

Abstract: On-chip photonic networks require adequately spatially ordered matter-photon interconversion qubit sources with emission figures-of-merit exceeding the requirements that would enable the desired functional response of the network. The mesa-top single quantum dots (MTSQDs) have recently been demonstrated to meet these requirements. The substrate-encoded size-reducing epitaxy (SESRE) approach underpinning the realization of these quantum emitters allows control on the shape, size, and strain (lattice-matched or mismatched) of these epitaxial single quantum dots. We have exploited this unique feature of the MTSQDs to reproducibly create arrays of quantum dots that exhibit single photon superradiance, characteristic of a delicate balance between the confinement potential volume, depth, and the resulting binding energy of the center of mass motion of the exciton and the exciton binding energy. In the exciton's weak confinement regime, direct enhancement of the quantum dot oscillator strength to ~30 is demonstrated for emitters in large arrays. Our findings provide compelling incentive for investigations of the potential of SESRE based tailored MTSQDs of lattice matched and mismatched material combinations for fabricating and studying interconnected networks enabled by these unique matter qubit-light qubit interconversion units.