Quantum walks in synthetic gauge fields with 3D integrated photonics

TL;DR

This paper proposes using 3D integrated photonic circuits to realize 2D quantum walks with synthetic gauge fields, demonstrating enhanced transport and topological protection, paving the way for robust quantum information processing.

Contribution

It introduces a flexible platform for implementing 2D quantum walks with synthetic gauge fields in 3D photonics, including Abelian and non-Abelian cases, for topologically robust transport.

Findings

Magnetic fields enhance transport via topologically protected edge states.

Polarization-dependent phase shifts enable non-Abelian gauge fields.

Platform facilitates study of multi-particle quantum walks with topological robustness.

Abstract

There is great interest in designing photonic devices capable of disorder-resistant transport and information processing. In this work we propose to exploit 3D integrated photonic circuits in order to realize 2D discrete-time quantum walks in a background synthetic gauge field. The gauge fields are generated by introducing the appropriate phase shifts between waveguides. Polarization-independent phase shifts lead to an Abelian or magnetic field, a case we describe in detail. We find that, in the disordered case, the magnetic field enhances transport due to the presence of topologically protected chiral edge states which do not localize. Polarization-dependent phase shifts lead to effective non-Abelian gauge fields, which could be adopted to realize Rashba-like quantum walks with spin-orbit coupling. Our work introduces a flexible platform for the experimental study of multi-particle quantum walks in the presence of synthetic gauge fields, which paves the way towards topologically robust transport of many-body states of photons.