English

Electrically-triggered spin-photon devices in silicon

Quantum Physics 2026-04-29 v1

Abstract

Quantum networking and computing technologies demand scalable hardware with high-speed control for large systems of quantum devices. Solid-state platforms have emerged as promising candidates, offering scalable fabrication for a wide range of qubits. Architectures based on spin-photon interfaces allow for highly-connected quantum networks over photonic links, enabling entanglement distribution for quantum networking and distributed quantum computing protocols. With the potential to address these demands, optically-active spin defects in silicon are one proposed platform for building quantum technologies. Here, we electrically excite the silicon T centre in integrated optoelectronic devices that combine nanophotonic waveguides and cavities with p-i-n diodes. We observe single-photon electroluminescence from a cavity-coupled T centre with g(2)(0)=0.05(2)g^{(2)}(0)=0.05(2). Further, we use the electrically-triggered emission to herald the electron spin state, initializing it with 92(8)%92(8)\% fidelity. This shows, for the first time, electrically-injected single-photon emission from a silicon colour centre and a new method of electrically-triggered spin initialization. These findings present a new telecommunications band light source for silicon and a highly parallel control method for T centre quantum processors, advancing the T centre as a versatile defect for scalable quantum technologies.

Keywords

Cite

@article{arxiv.2501.10597,
  title  = {Electrically-triggered spin-photon devices in silicon},
  author = {Michael Dobinson and Camille Bowness and Simon A. Meynell and Camille Chartrand and Elianor Hoffmann and Melanie Gascoine and Iain MacGilp and Francis Afzal and Christian Dangel and Navid Jahed and Michael L. W. Thewalt and Stephanie Simmons and Daniel B. Higginbottom},
  journal= {arXiv preprint arXiv:2501.10597},
  year   = {2026}
}

Comments

12 pages and 3 figures in main manuscript; 8 pages and 8 figures in supplementary information

R2 v1 2026-06-28T21:09:57.145Z