Quantum transport simulations in a programmable nanophotonic processor

Environmental noise and disorder play critical roles in quantum particle and wave transport in complex media, including solid-state and biological systems. Recent work has predicted that coupling between noisy environments and disordered systems, in which coherent transport has been arrested due to...

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Veröffentlicht in:	arXiv.org 2020-01
Hauptverfasser:	Harris, Nicholas C, Steinbrecher, Gregory R, Mower, Jacob, Lahini, Yoav, Prabhu, Mihika, Bunandar, Darius, Chen, Changchen, Wong, Franco N C, Baehr-Jones, Tom, Hochberg, Michael, Lloyd, Seth, Englund, Dirk
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Sprache:	eng
Schlagworte:	Background noise Complex media Computer simulation Finite element method Integrated circuits Microprocessors Photonics Physics - Optics Physics - Quantum Physics Quantum transport
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creator	Harris, Nicholas C Steinbrecher, Gregory R Mower, Jacob Lahini, Yoav Prabhu, Mihika Bunandar, Darius Chen, Changchen Wong, Franco N C Baehr-Jones, Tom Hochberg, Michael Lloyd, Seth Englund, Dirk
description	Environmental noise and disorder play critical roles in quantum particle and wave transport in complex media, including solid-state and biological systems. Recent work has predicted that coupling between noisy environments and disordered systems, in which coherent transport has been arrested due to localization effects, could actually enhance transport. Photonic integrated circuits are promising platforms for studying such effects, with a central goal being the development of large systems providing low-loss, high-fidelity control over all parameters of the transport problem. Here, we fully map the role of disorder in quantum transport using a nanophotonic processor consisting of a mesh of 88 generalized beamsplitters programmable on microsecond timescales. Over 64,400 transport experiments, we observe several distinct transport regimes, including environment-assisted quantum transport and the ''quantum Goldilocks'' regime in strong, statically disordered discrete-time systems. Low loss and high-fidelity programmable transformations make this nanophotonic processor a promising platform for many-boson quantum simulation experiments.
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subjects	Background noise Complex media Computer simulation Finite element method Integrated circuits Microprocessors Photonics Physics - Optics Physics - Quantum Physics Quantum transport
title	Quantum transport simulations in a programmable nanophotonic processor
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