Self-Configuring Quantum Networks with Superposition of Trajectories

Oral-In-person

Abstract

Quantum networks are a backbone of future quantum technologies thanks to their role in communication and scalable quantum computing. However, their performance is challenged by noise and decoherence. We propose a self-configuring approach that integrates superposed quantum paths with variational quantum optimization techniques. This allows networks to dynamically optimize the superposition of noisy paths across multiple nodes to establish high-fidelity connections between different parties. Our framework acts as a black box, capable of adapting to unknown noise without requiring characterization or benchmarking of the corresponding quantum channels. We also discuss the role of vacuum coherence, a quantum effect central to path superposition that impacts protocol performance. Additionally, we demonstrate that our approach remains beneficial even in the presence of imperfections in the generation of path superposition.

Publication: 1. J. Miguel-Ramiro et al., Phys. Rev. Lett. 131, 230601
2. J. Miguel-Ramiro et al., Phys. Rev. Res. 3, 033038
3. J. Miguel-Ramiro et al., Phys. Rev. A 108, 062604

Presenters

  • Albie Chan

    • University of Waterloo

Authors

  • Albie Chan

    • University of Waterloo
  • Zheng Shi

    • University of Waterloo
  • Christine Muschik

    • Institute for Quantum Computing
  • Luca Dellantonio

    • University of Waterloo
  • Wolfgang Dur

  • Jorge Miguel-Ramiro