English

Recirculating Quantum Photonic Networks for Fast Deterministic Quantum Information Processing

Quantum Physics 2026-02-12 v1

Abstract

A fundamental challenge in photonics-based deterministic quantum information processing is to realize key transformations on time scales shorter than those of detrimental decoherence and loss mechanisms. This challenge has been addressed through device-focused approaches that aim to increase nonlinear interactions relative to decoherence rates. In this work, we adopt a complementary architecture-focused approach by proposing a recirculating quantum photonic network (RQPN) that minimizes the duration of quantum information processing tasks, thereby reducing the requirements on nonlinear interaction rates. The RQPN consists of a network of all-to-all connected nonlinear cavities with dynamically controlled waveguide couplings, and it processes information by capturing a photonic input state, recirculating photons between the cavities, and releasing a photonic output state. We demonstrate the RQPN's architectural advantage through two examples: first, we show that processing all qubits simultaneously yields faster operations than single- and two-qubit decompositions of the three-qubit Toffoli gate. Second, we demonstrate implementations of a measurement-free correction for single-photon loss, achieving up to seven-fold speedups and significantly improved hardware efficiency relative to state-of-the-art architecture proposals. Our work shows that a single hardware-efficient recirculating architecture substantially reduces the temporal overhead of multi-qubit gates and quantum error correction, thereby lowering the barrier to experimental realizations of deterministic photonic quantum information processing.

Keywords

Cite

@article{arxiv.2602.11033,
  title  = {Recirculating Quantum Photonic Networks for Fast Deterministic Quantum Information Processing},
  author = {Emil Grovn and Matias Bundgaard-Nielsen and Jesper Mørk and Dirk Englund and Mikkel Heuck},
  journal= {arXiv preprint arXiv:2602.11033},
  year   = {2026}
}

Comments

Main text is 8 pages with 4 figures. Supplemental Material is included. The manuscript has been submitted for peer review

R2 v1 2026-07-01T10:32:10.922Z