Litcius/Paper detail

Shaping the Emission Directivity of Single Quantum Dots in Dielectric Nanodisks Exploiting Mie Resonances

Cristina Cruciano, Davide Rocco, Armando Genco, Andrea Tognazzi, Andrea Locatelli, Luca Carletti, Alexey Fedorov, Chiara Trovatello, Giuseppe Di Blasio, Ilaria Bargigia, Charalambos Louca, Paolo Gubian, Giulio Tavani, Luca Lovisolo, Artur Tuktamyshev, Lucio Claudio Andreani, Mattéo Galli, Giulio Cerullo, Giuseppe Leo, S. Sanguinetti, Costantino De Angelis, Monica Bollani

2025ACS Nano9 citationsDOIOpen Access PDF

Abstract

Manipulating the optical landscape of single quantum dots (QDs) is essential to increase the emitted photon output, enhancing their performance as chemical sensors and single-photon sources. Micro-optical structures are typically used for this task, with the drawback of a large size compared to the embedded single emitters. Nanophotonic architectures hold the promise to modify dramatically the emission properties of QDs, boosting light-matter interactions at the nanoscale, in ultracompact devices. Here, we investigate the interplay between gallium arsenide (GaAs) single QDs and aluminum gallium arsenide (AlGaAs) nanostructures, capitalizing on the Kerker condition for precise control of the QD emission directivity. An extensive analysis of the photoluminescence spectra of several QDs embedded in nanodisks revealed a pronounced directivity enhancement due to the Kerker effect, confirmed by theoretical simulations, resulting in a 14-fold increase of emitted intensity. Angle-resolved spectroscopy experiments also proved that the integration of GaAs QDs within nanostructures determines a precise angled emission, offering a distinctive avenue for manipulating the spatial characteristics of emitted light by exploiting Mie resonances. This work contributes to the optimization of QD integration in nanostructures and suggests potential improvements for applications in optical communications.

Topics & Concepts

Quantum dotMaterials scienceOptoelectronicsPhotoluminescenceGallium arsenideNanophotonicsDirectivityPhotonDielectricNanotechnologyOpticsPhysicsComputer scienceTelecommunicationsAntenna (radio)Semiconductor Quantum Structures and DevicesQuantum Dots Synthesis And PropertiesPlasmonic and Surface Plasmon Research
Shaping the Emission Directivity of Single Quantum Dots in Dielectric Nanodisks Exploiting Mie Resonances | Litcius