On the convergence of multi-scale free energy simulations

Gerhard König; Bernard R. Brooks; Walter Thiel; Darrin M. York

doi:10.1080/08927022.2018.1475741

On the convergence of multi-scale free energy simulations

Gerhard König, Bernard R. Brooks, Walter Thiel, Darrin M. York

Research output: Contribution to journal › Article › peer-review

36 Scopus citations

Abstract

In this work, we employ simple model systems to evaluate the relative performance of two of the most important free energy methods: The Zwanzig equation (also known as ‘Free energy perturbation’) and Bennett’s acceptance ratio method (BAR). Although our examples should be transferable to other kinds of free energy simulations, we focus on applications of multi-scale free energy simulations. Such calculations are especially complex, since they connect two different levels of theory with very different requirements in terms of speed, accuracy, sampling and parallelisability. We try to reconcile all those different factors by developing some simple criteria to guide the early stages of the development of a free energy protocol. This is accomplished by quantifying how many (Formula presented.) intermediate steps and how many potential energy evaluations are necessary in order to reach a certain level of convergence.

Original language	English (US)
Pages (from-to)	1062-1081
Number of pages	20
Journal	Molecular Simulation
Volume	44
Issue number	13-14
DOIs	https://doi.org/10.1080/08927022.2018.1475741
State	Published - Sep 22 2018

All Science Journal Classification (ASJC) codes

Chemistry(all)
Information Systems
Modeling and Simulation
Chemical Engineering(all)
Materials Science(all)
Condensed Matter Physics

Keywords

Free energy protocol design
convergence properties
multi-scale simulations

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10.1080/08927022.2018.1475741

Cite this

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abstract = "In this work, we employ simple model systems to evaluate the relative performance of two of the most important free energy methods: The Zwanzig equation (also known as {\textquoteleft}Free energy perturbation{\textquoteright}) and Bennett{\textquoteright}s acceptance ratio method (BAR). Although our examples should be transferable to other kinds of free energy simulations, we focus on applications of multi-scale free energy simulations. Such calculations are especially complex, since they connect two different levels of theory with very different requirements in terms of speed, accuracy, sampling and parallelisability. We try to reconcile all those different factors by developing some simple criteria to guide the early stages of the development of a free energy protocol. This is accomplished by quantifying how many (Formula presented.) intermediate steps and how many potential energy evaluations are necessary in order to reach a certain level of convergence.",

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PY - 2018/9/22

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N2 - In this work, we employ simple model systems to evaluate the relative performance of two of the most important free energy methods: The Zwanzig equation (also known as ‘Free energy perturbation’) and Bennett’s acceptance ratio method (BAR). Although our examples should be transferable to other kinds of free energy simulations, we focus on applications of multi-scale free energy simulations. Such calculations are especially complex, since they connect two different levels of theory with very different requirements in terms of speed, accuracy, sampling and parallelisability. We try to reconcile all those different factors by developing some simple criteria to guide the early stages of the development of a free energy protocol. This is accomplished by quantifying how many (Formula presented.) intermediate steps and how many potential energy evaluations are necessary in order to reach a certain level of convergence.

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On the convergence of multi-scale free energy simulations

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