Deterministically Fabricated Solid-State Quantum-Light Sources

TL;DR

This review discusses deterministic fabrication methods for solid-state quantum-light sources, focusing on material systems, techniques, and recent advancements that enable scalable quantum photonic applications.

Contribution

It provides a comprehensive overview of fabrication techniques, including in-situ and hybrid methods, and highlights recent progress in quantum-dot based sources for quantum technologies.

Findings

Advances in in-situ fabrication techniques improved source performance.

Hybrid pick-and-place methods enable precise integration of quantum emitters.

State-of-the-art sources show enhanced photon collection efficiency.

Abstract

This topical review focuses on solid-state quantum-light sources which are fabricated in a deterministic fashion. In this framework we cover quantum emitters represented by semiconductor quantum dots, colour centres in diamond, and defect-/strain-centres in two-dimensional materials. First, we introduce the topic of quantum-light sources and non-classical light generation for applications in photonic quantum technologies, motivating the need for the development of scalable device technologies to push the field to real-world applications. In the second part, we summarize material systems hosting quantum emitters in the solid-state. The third part reviews deterministic fabrication techniques and comparatively discusses their advantages and disadvantages. The techniques are classified in bottom-up approaches, exploiting the site-controlled positioning of the quantum emitters themselves, and top-down approaches, allowing for the precise alignment of photonic microstructures to pre-selected quantum emitters. Special emphasis is put on the progress achieved in the development of in-situ techniques, which significantly pushed the performance of quantum-light sources towards applications. Additionally we discuss hybrid approaches, exploiting pick-and-place techniques or wafer-bonding. The fourth part presents state-of-the-art quantum-dot quantum-light sources based on the fabrication techniques presented in the previous sections, which feature engineered functionality and enhanced photon collection efficiency. The article closes by highlighting recent applications of deterministic solid-state-based quantum-light sources in the fields of quantum communication, quantum computing, and quantum metrology, and discussing future perspectives in the field of solid-state quantum-light sources.