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Data-driven approximations to the bridge function yield improved closures for the Ornstein–Zernike equation

Rhys E. A. Goodall, Alpha A. Lee

2021Soft Matter17 citationsDOIOpen Access PDF

Abstract

A key challenge for soft materials design and coarse-graining simulations is determining interaction potentials between components that give rise to desired condensed-phase structures. In theory, the Ornstein-Zernike equation provides an elegant framework for solving this inverse problem. Pioneering work in liquid state theory derived analytical closures for the framework. However, these analytical closures are approximations, valid only for specific classes of interaction potentials. In this work, we combine the physics of liquid state theory with machine learning to infer a closure directly from simulation data. The resulting closure is more accurate than commonly used closures across a broad range of interaction potentials.

Topics & Concepts

Zernike polynomialsOrnstein–Zernike equationBridge (graph theory)Yield (engineering)Statistical physicsFunction (biology)PhysicsMathematicsMathematical analysisIntegral equationThermodynamicsQuantum mechanicsBiologyInternal medicineWavefrontMedicineEvolutionary biologyMachine Learning in Materials ScienceQuantum many-body systemsQuantum, superfluid, helium dynamics
Data-driven approximations to the bridge function yield improved closures for the Ornstein–Zernike equation | Litcius