English

Near-deterministic photon entanglement from a spin qudit in silicon using third quantisation

Quantum Physics 2026-04-02 v2 Mesoscale and Nanoscale Physics

Abstract

Unlike other quantum hardware, photonic quantum architectures can produce millions of qubits from a single device. However, controlling photonic qubits remains challenging, even at small scales, due to their weak interactions, making non-deterministic gates in linear optics unavoidable. Nevertheless, a single photon can readily spread over multiple modes and create entanglement within the multiple modes deterministically. Rudolph's concept of third quantization leverages this feature by evolving multiple single-photons into multiple modes, distributing them uniformly and randomly to different parties, and creating multipartite entanglement without interactions between photons or non-deterministic gates. This method requires only classical communication and deterministic entanglement within multi-mode single-photon states and enables universal quantum computing. The multipartite entanglement generated within the third quantization framework is nearly deterministic, where ``deterministic'' is achieved in the asymptotic limit of a large system size. In this work, we propose a near-term experiment using antimony donor in a silicon chip to realize third quantization. Utilizing the eight energy levels of antimony, one can generate two eight-mode single-photon states independently and distribute them to parties. This enables a random multipartite Bell-state experiment, achieving a Bell state with an upper-bound efficiency of 87.5% among 56 random pairs without non-deterministic entangling gates. This approach opens alternative pathways for silicon-based photonic quantum computing.

Keywords

Cite

@article{arxiv.2502.01096,
  title  = {Near-deterministic photon entanglement from a spin qudit in silicon using third quantisation},
  author = {Gözde Üstün and Samuel Elman and Jarryd J. Pla and Andrew C. Doherty and Andrea Morello and Simon J. Devitt},
  journal= {arXiv preprint arXiv:2502.01096},
  year   = {2026}
}

Comments

17 pages including appendix information

R2 v1 2026-06-28T21:30:01.985Z