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Learning Mappings between Equilibrium States of Liquid Systems Using Normalizing Flows

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arxiv 2208.10420 v1 pith:DIGF7IB3 submitted 2022-08-22 physics.comp-ph cond-mat.stat-mech

Learning Mappings between Equilibrium States of Liquid Systems Using Normalizing Flows

classification physics.comp-ph cond-mat.stat-mech
keywords systemsliquidtransformationdifferentequilibriumflowslennard-jonesmodels
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Generative models are a promising tool to address the sampling problem in multi-body and condensed-matter systems in the framework of statistical mechanics. In this work, we show that normalizing flows can be used to learn a transformation to map different liquid systems into each other allowing at the same time to obtain an unbiased equilibrium distribution through a reweighting process. Two proof-of-principles calculations are presented for the transformation between Lennard-Jones systems of particles with different depths of the potential well and for the transformation between a Lennard-Jones and a system of repulsive particles. In both numerical experiments, systems are in the liquid state. In future applications, this approach could lead to efficient methods to simulate liquid systems at ab-initio accuracy with the computational cost of less accurate models, such as force field or coarse-grained simulations.

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