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Mitigating the Hubbard sign problem with complex-valued neural networks

Marcel Rodekamp, Evan Berkowitz, Christoph Gäntgen, Stefan Krieg, Thomas Luu, Johann Ostmeyer

2022Physical review. B./Physical review. B19 citationsDOI

Abstract

Monte Carlo simulations away from half filling suffer from a sign problem that can be reduced by deforming the contour of integration. Such a transformation, which induces a Jacobian determinant in the Boltzmann weight, can be implemented using neural networks. This additional determinant cost for a generic neural network scales cubically with the volume, preventing large-scale simulations. We implement an architecture, based on complex-valued affine coupling layers, which reduces this to linear scaling. We demonstrate the efficacy of this method by successfully applying it to systems of different size, the largest of which is intractable by other Monte Carlo methods due to its severe sign problem.

Topics & Concepts

Jacobian matrix and determinantSign (mathematics)Artificial neural networkAffine transformationMonte Carlo methodComputer scienceStatistical physicsQuantum Monte CarloLinear scaleHubbard modelScalingBoltzmann constantBoltzmann machineCoupling (piping)Scale (ratio)AlgorithmApplied mathematicsMathematical optimizationPhysicsArtificial intelligenceMathematicsQuantum mechanicsMathematical analysisGeometryMaterials scienceSuperconductivityGeodesyStatisticsMetallurgyGeographyModel Reduction and Neural NetworksQuantum many-body systemsTheoretical and Computational Physics
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