Deterministic Quantum Light Arrays from Giant Silica-Shelled Quantum Dots
Publication Date:
December 12 2022
Article Citation:
ACS Applied Materials & Interfaces., 2023, 15, 3, 4294-4302
Article Authors
Hao A. Nguyen, David Sharp, Johannes E. Fröch, Yi-Yu Cai, Shenwei Wu, Madison Monahan, Christopher Munley, Arnab Manna, Arka Majumdar, Cherie R. Kagan, and Brandi M. Cossairt
Article DOI:
https://doi.org/10.1021/acsami.2c18475
Research Thrusts:
RT-1 | RT-2 | RT-3
Topic Areas:
Colloidal Synthesis | Deterministic Positioning | Quantum Dots | Silica Shelling | Single-Photon Sources

Colloidal quantum dots (QDs) are promising candidates for single-photon sources with applications in photonic quantum information technologies. Developing practical photonic quantum devices with colloidal materials, however, requires scalable deterministic placement of stable single QD emitters. In this work, we describe a method to exploit QD size to facilitate deterministic positioning of single QDs into large arrays while maintaining their photostability and single-photon emission properties. CdSe/CdS core/shell QDs were encapsulated in silica to both increase their physical size without perturbing their quantum-confined emission and enhance their photostability.

These giant QDs were then precisely positioned into ordered arrays using template-assisted self-assembly with a 75% yield for single QDs. We show that the QDs before and after assembly exhibit antibunching behavior at room temperature and their optical properties are retained after an extended period of time. Together, this bottom-up synthetic approach via silica shelling and the robust template-assisted self-assembly offer a unique strategy to produce scalable quantum photonics platforms using colloidal QDs as single-photon emitters.