Related papers: Boson sampling discrete solitons by quantum machine learning

Boson sampling discrete solitons by quantum machine learning

URL: http://arxiv.org/abs/2110.12379v1
Date: Sun, 24 Oct 2021 07:48:51 GMT
Title: Boson sampling discrete solitons by quantum machine learning
Authors: Claudio Conti
Abstract summary: We find different quantum soliton solutions varying the number of particles and interaction strength. The use of Gaussian states enables measuring the degree of entanglement and the boson sampling patterns. Results may have a role in boson sampling experiments with nonlinear systems and in developing quantum processors to generate entangled many-photon nonlinear states.
Score: 0.11421942894219898
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We use a neural network variational ansatz to compute Gaussian quantum discrete solitons in an array of waveguides described by the quantum discrete nonlinear Schroedinger equation. By training the quantum machine learning model in the phase space, we find different quantum soliton solutions varying the number of particles and interaction strength. The use of Gaussian states enables measuring the degree of entanglement and the boson sampling patterns. We compute the probability of generating different particle pairs when varying the soliton features and unveil that bound states of discrete solitons emit correlated pairs of photons. These results may have a role in boson sampling experiments with nonlinear systems and in developing quantum processors to generate entangled many-photon nonlinear states.

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