Quantum walks are powerful tools for building quantum algorithms, modeling transport phenomena, and designing topological systems. Here we present a photonic implementation of a quantum walk in two spatial dimensions, where the lattice of walker positions is encoded in the transverse-wavevector components of a paraxial light beam. The desired quantum dynamics is obtained by means of a sequence of liquid-crystal devices ("g-plates"), which apply polarization-dependent transverse kicks to the photons in the beam. We first characterize our setup, and then benchmark it by implementing a periodically-driven Chern insulator and probing its topological features. Our platform is compact, versatile and cost-effective: most evolution parameters are controlled dynamically, the walker distribution is detected in a single shot, and the input state can be tailored at will. These features offer exciting prospects for the photonic simulation of two-dimensional quantum systems.
Two-dimensional topological quantum walks in the momentum space of structured light / D'Errico, Alessio; Cardano, Filippo; Maffei, Maria; Dauphin, Alexandre; Barboza, Raouf; Esposito, Chiara; Piccirillo, Bruno; Lewenstein, Maciej; Massignan, Pietro; Marrucci, Lorenzo. - In: OPTICA. - ISSN 2334-2536. - 7:2(2020), pp. 108-114. [10.1364/OPTICA.365028]
Two-dimensional topological quantum walks in the momentum space of structured light
Chiara Esposito;Lorenzo Marrucci
2020
Abstract
Quantum walks are powerful tools for building quantum algorithms, modeling transport phenomena, and designing topological systems. Here we present a photonic implementation of a quantum walk in two spatial dimensions, where the lattice of walker positions is encoded in the transverse-wavevector components of a paraxial light beam. The desired quantum dynamics is obtained by means of a sequence of liquid-crystal devices ("g-plates"), which apply polarization-dependent transverse kicks to the photons in the beam. We first characterize our setup, and then benchmark it by implementing a periodically-driven Chern insulator and probing its topological features. Our platform is compact, versatile and cost-effective: most evolution parameters are controlled dynamically, the walker distribution is detected in a single shot, and the input state can be tailored at will. These features offer exciting prospects for the photonic simulation of two-dimensional quantum systems.File | Dimensione | Formato | |
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