Achieving Reproducibility and Replicability of Molecular Dynamics and Monte Carlo Simulations Using the Molecular Simulation Design Framework (MoSDeF)

Nicholas C. Craven; Ramanish Singh; Co D. Quach; Justin B. Gilmer; Brad Crawford; Eliseo Marin-Rimoldi; Ryan Smith; Ryan DeFever; Maxim S. Dyukov; Jenny W. Fothergill; Chris Jones; Timothy C. Moore; Brandon L. Butler; Joshua A. Anderson; Christopher R. Iacovella; Eric Jankowski; Edward J. Maginn; Jeffrey J. Potoff; Sharon C. Glotzer; Peter T. Cummings; Clare McCabe; J. Ilja Siepmann

doi:10.1021/acs.jced.5c00010

Achieving Reproducibility and Replicability of Molecular Dynamics and Monte Carlo Simulations Using the Molecular Simulation Design Framework (MoSDeF)

Nicholas C. Craven, Ramanish Singh, Co D. Quach, Justin B. Gilmer, Brad Crawford, Eliseo Marin-Rimoldi, Ryan Smith, Ryan DeFever, Maxim S. Dyukov, Jenny W. Fothergill, Chris Jones, Timothy C. Moore, Brandon L. Butler, Joshua A. Anderson, Christopher R. Iacovella, Eric Jankowski, Edward J. Maginn, Jeffrey J. Potoff, Sharon C. Glotzer, Peter T. CummingsClare McCabe, J. Ilja Siepmann

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Abstract

Molecular simulations are increasingly used to predict thermophysical properties and explore molecular-level phenomena beyond modern imaging techniques. To make these tools accessible to nonexperts, several open-source molecular dynamics (MD) and Monte Carlo (MC) codes have been developed. However, using these tools is challenging, and concerns about the validity and reproducibility of the simulation data persist. In 2017, Schappals et al. reported a benchmarking study involving several research groups independently performing MD and MC simulations using different software to predict densities of alkanes using common molecular mechanics force fields [ J. Chem. Theory Comput. 2017, 4270−4280]. Although the predicted densities were reasonably close (mostly within 1%), the data often fell outside of the combined statistical uncertainties of the different simulations. Schappals et al. concluded that there are unavoidable errors inherent to molecular simulations once a certain degree of complexity of the system is reached. The Molecular Simulation Design Framework (MoSDeF) is a workflow package designed to achieve TRUE (Transparent, Reproducible, Usable-by-others, and Extensible) simulation studies by standardizing the implementation of molecular models for various simulation engines. This work demonstrates that using MoSDeF to initialize a simulation workflow results in consistent predictions of system density, even while increasing model complexity.

Original language	English
Pages (from-to)	2178-2199
Number of pages	22
Journal	Journal of Chemical and Engineering Data
Volume	70
Issue number	6
Early online date	27 May 2025
DOIs	https://doi.org/10.1021/acs.jced.5c00010 https://doi.org/10.1021/acs.jced.5c00010
Publication status	Published - 12 Jun 2025

Keywords

Algorithms
Computational chemistry
Computer simulations
Molecular mechanics
Molecules

ASJC Scopus subject areas

General Chemistry
General Chemical Engineering

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Craven, N. C., Singh, R., Quach, C. D., Gilmer, J. B., Crawford, B., Marin-Rimoldi, E., Smith, R., DeFever, R., Dyukov, M. S., Fothergill, J. W., Jones, C., Moore, T. C., Butler, B. L., Anderson, J. A., Iacovella, C. R., Jankowski, E., Maginn, E. J., Potoff, J. J., Glotzer, S. C., ... Siepmann, J. I. (2025). Achieving Reproducibility and Replicability of Molecular Dynamics and Monte Carlo Simulations Using the Molecular Simulation Design Framework (MoSDeF). Journal of Chemical and Engineering Data, 70(6), 2178-2199. https://doi.org/10.1021/acs.jced.5c00010, https://doi.org/10.1021/acs.jced.5c00010

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title = "Achieving Reproducibility and Replicability of Molecular Dynamics and Monte Carlo Simulations Using the Molecular Simulation Design Framework (MoSDeF)",

abstract = "Molecular simulations are increasingly used to predict thermophysical properties and explore molecular-level phenomena beyond modern imaging techniques. To make these tools accessible to nonexperts, several open-source molecular dynamics (MD) and Monte Carlo (MC) codes have been developed. However, using these tools is challenging, and concerns about the validity and reproducibility of the simulation data persist. In 2017, Schappals et al. reported a benchmarking study involving several research groups independently performing MD and MC simulations using different software to predict densities of alkanes using common molecular mechanics force fields [ J. Chem. Theory Comput. 2017, 4270−4280]. Although the predicted densities were reasonably close (mostly within 1%), the data often fell outside of the combined statistical uncertainties of the different simulations. Schappals et al. concluded that there are unavoidable errors inherent to molecular simulations once a certain degree of complexity of the system is reached. The Molecular Simulation Design Framework (MoSDeF) is a workflow package designed to achieve TRUE (Transparent, Reproducible, Usable-by-others, and Extensible) simulation studies by standardizing the implementation of molecular models for various simulation engines. This work demonstrates that using MoSDeF to initialize a simulation workflow results in consistent predictions of system density, even while increasing model complexity.",

keywords = "Algorithms, Computational chemistry, Computer simulations, Molecular mechanics, Molecules",

author = "Craven, {Nicholas C.} and Ramanish Singh and Quach, {Co D.} and Gilmer, {Justin B.} and Brad Crawford and Eliseo Marin-Rimoldi and Ryan Smith and Ryan DeFever and Dyukov, {Maxim S.} and Fothergill, {Jenny W.} and Chris Jones and Moore, {Timothy C.} and Butler, {Brandon L.} and Anderson, {Joshua A.} and Iacovella, {Christopher R.} and Eric Jankowski and Maginn, {Edward J.} and Potoff, {Jeffrey J.} and Glotzer, {Sharon C.} and Cummings, {Peter T.} and Clare McCabe and Siepmann, {J. Ilja}",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors. Published by American Chemical Society.",

year = "2025",

month = jun,

day = "12",

doi = "10.1021/acs.jced.5c00010",

language = "English",

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Craven, NC, Singh, R, Quach, CD, Gilmer, JB, Crawford, B, Marin-Rimoldi, E, Smith, R, DeFever, R, Dyukov, MS, Fothergill, JW, Jones, C, Moore, TC, Butler, BL, Anderson, JA, Iacovella, CR, Jankowski, E, Maginn, EJ, Potoff, JJ, Glotzer, SC, Cummings, PT , McCabe, C & Siepmann, JI 2025, 'Achieving Reproducibility and Replicability of Molecular Dynamics and Monte Carlo Simulations Using the Molecular Simulation Design Framework (MoSDeF)', Journal of Chemical and Engineering Data, vol. 70, no. 6, pp. 2178-2199. https://doi.org/10.1021/acs.jced.5c00010, https://doi.org/10.1021/acs.jced.5c00010

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T1 - Achieving Reproducibility and Replicability of Molecular Dynamics and Monte Carlo Simulations Using the Molecular Simulation Design Framework (MoSDeF)

AU - Craven, Nicholas C.

AU - Singh, Ramanish

AU - Quach, Co D.

AU - Gilmer, Justin B.

AU - Crawford, Brad

AU - Marin-Rimoldi, Eliseo

AU - Smith, Ryan

AU - DeFever, Ryan

AU - Dyukov, Maxim S.

AU - Fothergill, Jenny W.

AU - Jones, Chris

AU - Moore, Timothy C.

AU - Butler, Brandon L.

AU - Anderson, Joshua A.

AU - Iacovella, Christopher R.

AU - Jankowski, Eric

AU - Maginn, Edward J.

AU - Potoff, Jeffrey J.

AU - Glotzer, Sharon C.

AU - Cummings, Peter T.

AU - McCabe, Clare

AU - Siepmann, J. Ilja

PY - 2025/6/12

Y1 - 2025/6/12

N2 - Molecular simulations are increasingly used to predict thermophysical properties and explore molecular-level phenomena beyond modern imaging techniques. To make these tools accessible to nonexperts, several open-source molecular dynamics (MD) and Monte Carlo (MC) codes have been developed. However, using these tools is challenging, and concerns about the validity and reproducibility of the simulation data persist. In 2017, Schappals et al. reported a benchmarking study involving several research groups independently performing MD and MC simulations using different software to predict densities of alkanes using common molecular mechanics force fields [ J. Chem. Theory Comput. 2017, 4270−4280]. Although the predicted densities were reasonably close (mostly within 1%), the data often fell outside of the combined statistical uncertainties of the different simulations. Schappals et al. concluded that there are unavoidable errors inherent to molecular simulations once a certain degree of complexity of the system is reached. The Molecular Simulation Design Framework (MoSDeF) is a workflow package designed to achieve TRUE (Transparent, Reproducible, Usable-by-others, and Extensible) simulation studies by standardizing the implementation of molecular models for various simulation engines. This work demonstrates that using MoSDeF to initialize a simulation workflow results in consistent predictions of system density, even while increasing model complexity.

AB - Molecular simulations are increasingly used to predict thermophysical properties and explore molecular-level phenomena beyond modern imaging techniques. To make these tools accessible to nonexperts, several open-source molecular dynamics (MD) and Monte Carlo (MC) codes have been developed. However, using these tools is challenging, and concerns about the validity and reproducibility of the simulation data persist. In 2017, Schappals et al. reported a benchmarking study involving several research groups independently performing MD and MC simulations using different software to predict densities of alkanes using common molecular mechanics force fields [ J. Chem. Theory Comput. 2017, 4270−4280]. Although the predicted densities were reasonably close (mostly within 1%), the data often fell outside of the combined statistical uncertainties of the different simulations. Schappals et al. concluded that there are unavoidable errors inherent to molecular simulations once a certain degree of complexity of the system is reached. The Molecular Simulation Design Framework (MoSDeF) is a workflow package designed to achieve TRUE (Transparent, Reproducible, Usable-by-others, and Extensible) simulation studies by standardizing the implementation of molecular models for various simulation engines. This work demonstrates that using MoSDeF to initialize a simulation workflow results in consistent predictions of system density, even while increasing model complexity.

KW - Algorithms

KW - Computational chemistry

KW - Computer simulations

KW - Molecular mechanics

KW - Molecules

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DO - 10.1021/acs.jced.5c00010

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JO - Journal of Chemical and Engineering Data

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Craven NC, Singh R, Quach CD, Gilmer JB, Crawford B, Marin-Rimoldi E et al. Achieving Reproducibility and Replicability of Molecular Dynamics and Monte Carlo Simulations Using the Molecular Simulation Design Framework (MoSDeF). Journal of Chemical and Engineering Data. 2025 Jun 12;70(6):2178-2199. Epub 2025 May 27. doi: 10.1021/acs.jced.5c00010, 10.1021/acs.jced.5c00010

Achieving Reproducibility and Replicability of Molecular Dynamics and Monte Carlo Simulations Using the Molecular Simulation Design Framework (MoSDeF)

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