Architecture-Independent Absolute Solvation Free Energy Calculations with Neural Network Potentials

Anna Katharina Picha; Sara Tkaczyk; Thierry Langer; Marcus Wieder; Stefan Boresch

doi:10.1021/acs.jpclett.5c02980

Architecture-Independent Absolute Solvation Free Energy Calculations with Neural Network Potentials

Anna Katharina Picha
, Sara Tkaczyk
, Thierry Langer
, Marcus Wieder (Corresponding author)
, Stefan Boresch (Corresponding author)

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Allowing atoms or molecules to disappear is a critical step in alchemical free energy simulations (FES). The necessary tricks are well understood when using force fields. Over the past few years, neural network potentials (NNPs) have seen rapid development. Their potentially higher accuracy compared to force fields makes them attractive for use in FES. Here, we outline a method for gradually decoupling atoms and molecules in systems that are fully described by NNPs. Specifically, we show that manipulating the neighbor list is equivalent to using soft-core potentials in force-field-based FES. Since constructing the neighbor list is a central step, regardless of the NNP’s inner workings, our approach is agnostic to NNP architecture. We validate the correctness of our methodology by demonstrating cycle closure for a model problem and report solvation free energies obtained with the MACE-OFF23(S/M) NNP.

Original language	English
Pages (from-to)	12080-12086
Number of pages	7
Journal	Journal of Physical Chemistry Letters
Volume	16
DOIs	https://doi.org/10.1021/acs.jpclett.5c02980
Publication status	Published - 2025

Austrian Fields of Science 2012

104017 Physical chemistry
104027 Computational chemistry
102009 Computer simulation

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Cite this

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title = "Architecture-Independent Absolute Solvation Free Energy Calculations with Neural Network Potentials",

abstract = "Allowing atoms or molecules to disappear is a critical step in alchemical free energy simulations (FES). The necessary tricks are well understood when using force fields. Over the past few years, neural network potentials (NNPs) have seen rapid development. Their potentially higher accuracy compared to force fields makes them attractive for use in FES. Here, we outline a method for gradually decoupling atoms and molecules in systems that are fully described by NNPs. Specifically, we show that manipulating the neighbor list is equivalent to using soft-core potentials in force-field-based FES. Since constructing the neighbor list is a central step, regardless of the NNP{\textquoteright}s inner workings, our approach is agnostic to NNP architecture. We validate the correctness of our methodology by demonstrating cycle closure for a model problem and report solvation free energies obtained with the MACE-OFF23(S/M) NNP.",

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AU - Picha, Anna Katharina

AU - Tkaczyk, Sara

AU - Langer, Thierry

AU - Wieder, Marcus

AU - Boresch, Stefan

PY - 2025

Y1 - 2025

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Architecture-Independent Absolute Solvation Free Energy Calculations with Neural Network Potentials

Abstract

Austrian Fields of Science 2012

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