Accelerated Sequence Design of Star Block Copolymers: An Unbiased Exploration Strategy via Fusion of Molecular Dynamics Simulations and Machine Learning

Jan Michael Y. Carrillo; Vijith Parambil; Tarak K. Patra; Zhan Chen; Thomas P. Russell; Subramanian K.R.S. Sankaranarayanan; Bobby G. Sumpter; Rohit Batra

doi:10.1021/acs.jpcb.3c08110

Accelerated Sequence Design of Star Block Copolymers: An Unbiased Exploration Strategy via Fusion of Molecular Dynamics Simulations and Machine Learning

Jan Michael Y. Carrillo, Vijith Parambil, Tarak K. Patra, Zhan Chen, Thomas P. Russell, Subramanian K.R.S. Sankaranarayanan, Bobby G. Sumpter, Rohit Batra

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

1 Scopus citations

Abstract

Star block copolymers (s-BCPs) have potential applications as novel surfactants or amphiphiles for emulsification, compatibilization, chemical transformations, and separations. s-BCPs have chain architectures where three or more linear diblock copolymer arms comprised of two chemically distinct linear polymers, e.g., solvophobic and solvophilic chains, are covalently joined at one point. The chemical composition of each of the subunit polymer chains comprising the arms, their molecular weights, and the number of arms can be varied to tailor the surface and interfacial activity of these architecturally unique molecules. This makes identification of the optimal s-BCP design nontrivial as the total number of plausible s-BCP architectures is experimentally or computationally intractable. In this work, we use molecular dynamics (MD) simulations coupled with a reinforcement learning-based Monte Carlo tree search (MCTS) to identify s-BCP designs that minimize the interfacial tension between polar and nonpolar solvents. We first validate the MCTS approach for the design of small- and medium-sized s-BCPs and then use it to efficiently identify sequences of copolymer blocks for large-sized s-BCPs. The structural origins of interfacial tension in these systems are also identified by using the configurations obtained from MD simulations. Chemical insights into the arrangement of copolymer blocks that promote lower interfacial tension were mined using machine learning (ML) techniques. Overall, this work provides an efficient approach to solve design problems via fusion of simulations and ML and provides important groundwork for future experimental investigation of s-BCPs for various applications.

Original language	English
Pages (from-to)	4220-4230
Number of pages	11
Journal	Journal of Physical Chemistry B
Volume	128
Issue number	17
DOIs	https://doi.org/10.1021/acs.jpcb.3c08110
State	Published - May 2 2024

Funding

This material is based on work supported by the DOE, Office of Science, BES Data, Artificial Intelligence and Machine Learning at DOE Scientific User Facilities program (Digital Twins) under award number 34532. A part of this research was performed at the Center for Nanophase Materials Sciences (CNMS) at Oak Ridge National Laboratory which is a US Department of Energy (DOE) Office of Science User Facility. Use of the Center for Nanoscale Materials, an Office of Science user facility, was supported by the U.S. Department of Energy, Office of Science, Office of Basic Energy Sciences, under contract no. DE-AC02-06CH11357. MD simulations used resources of the Oak Ridge Leadership Computing Facility, which is supported by DOE Office of Science under contract DE-AC05-00OR22725, and National Energy Research Scientific Computing Center, a DOE Office of Science User Facility supported by the Office of Science of the U.S. Department of Energy under contract no. DE-AC02-05CH11231. R.B. acknowledges support from the Center for Atomistic Modelling and Materials Design under the IOE scheme, from ICSR, IIT Madras, for the initiation research grant, and from the Robert Bosch Centre for Data Science and AI (RBCDSAI). Z.C. and T.P.R. were supported by the Army Research Office under contract no. W911NF-24-2-0041.

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10.1021/acs.jpcb.3c08110

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Carrillo, J. M. Y., Parambil, V., Patra, T. K., Chen, Z., Russell, T. P., Sankaranarayanan, S. K. R. S., Sumpter, B. G., & Batra, R. (2024). Accelerated Sequence Design of Star Block Copolymers: An Unbiased Exploration Strategy via Fusion of Molecular Dynamics Simulations and Machine Learning. Journal of Physical Chemistry B, 128(17), 4220-4230. https://doi.org/10.1021/acs.jpcb.3c08110

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title = "Accelerated Sequence Design of Star Block Copolymers: An Unbiased Exploration Strategy via Fusion of Molecular Dynamics Simulations and Machine Learning",

abstract = "Star block copolymers (s-BCPs) have potential applications as novel surfactants or amphiphiles for emulsification, compatibilization, chemical transformations, and separations. s-BCPs have chain architectures where three or more linear diblock copolymer arms comprised of two chemically distinct linear polymers, e.g., solvophobic and solvophilic chains, are covalently joined at one point. The chemical composition of each of the subunit polymer chains comprising the arms, their molecular weights, and the number of arms can be varied to tailor the surface and interfacial activity of these architecturally unique molecules. This makes identification of the optimal s-BCP design nontrivial as the total number of plausible s-BCP architectures is experimentally or computationally intractable. In this work, we use molecular dynamics (MD) simulations coupled with a reinforcement learning-based Monte Carlo tree search (MCTS) to identify s-BCP designs that minimize the interfacial tension between polar and nonpolar solvents. We first validate the MCTS approach for the design of small- and medium-sized s-BCPs and then use it to efficiently identify sequences of copolymer blocks for large-sized s-BCPs. The structural origins of interfacial tension in these systems are also identified by using the configurations obtained from MD simulations. Chemical insights into the arrangement of copolymer blocks that promote lower interfacial tension were mined using machine learning (ML) techniques. Overall, this work provides an efficient approach to solve design problems via fusion of simulations and ML and provides important groundwork for future experimental investigation of s-BCPs for various applications.",

author = "Carrillo, {Jan Michael Y.} and Vijith Parambil and Patra, {Tarak K.} and Zhan Chen and Russell, {Thomas P.} and Sankaranarayanan, {Subramanian K.R.S.} and Sumpter, {Bobby G.} and Rohit Batra",

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doi = "10.1021/acs.jpcb.3c08110",

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Carrillo, JMY, Parambil, V, Patra, TK, Chen, Z, Russell, TP, Sankaranarayanan, SKRS, Sumpter, BG & Batra, R 2024, 'Accelerated Sequence Design of Star Block Copolymers: An Unbiased Exploration Strategy via Fusion of Molecular Dynamics Simulations and Machine Learning', Journal of Physical Chemistry B, vol. 128, no. 17, pp. 4220-4230. https://doi.org/10.1021/acs.jpcb.3c08110

Accelerated Sequence Design of Star Block Copolymers: An Unbiased Exploration Strategy via Fusion of Molecular Dynamics Simulations and Machine Learning. / Carrillo, Jan Michael Y.; Parambil, Vijith; Patra, Tarak K. et al.
In: Journal of Physical Chemistry B, Vol. 128, No. 17, 02.05.2024, p. 4220-4230.

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

TY - JOUR

T1 - Accelerated Sequence Design of Star Block Copolymers

T2 - An Unbiased Exploration Strategy via Fusion of Molecular Dynamics Simulations and Machine Learning

AU - Carrillo, Jan Michael Y.

AU - Parambil, Vijith

AU - Patra, Tarak K.

AU - Chen, Zhan

AU - Russell, Thomas P.

AU - Sankaranarayanan, Subramanian K.R.S.

AU - Sumpter, Bobby G.

AU - Batra, Rohit

PY - 2024/5/2

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N2 - Star block copolymers (s-BCPs) have potential applications as novel surfactants or amphiphiles for emulsification, compatibilization, chemical transformations, and separations. s-BCPs have chain architectures where three or more linear diblock copolymer arms comprised of two chemically distinct linear polymers, e.g., solvophobic and solvophilic chains, are covalently joined at one point. The chemical composition of each of the subunit polymer chains comprising the arms, their molecular weights, and the number of arms can be varied to tailor the surface and interfacial activity of these architecturally unique molecules. This makes identification of the optimal s-BCP design nontrivial as the total number of plausible s-BCP architectures is experimentally or computationally intractable. In this work, we use molecular dynamics (MD) simulations coupled with a reinforcement learning-based Monte Carlo tree search (MCTS) to identify s-BCP designs that minimize the interfacial tension between polar and nonpolar solvents. We first validate the MCTS approach for the design of small- and medium-sized s-BCPs and then use it to efficiently identify sequences of copolymer blocks for large-sized s-BCPs. The structural origins of interfacial tension in these systems are also identified by using the configurations obtained from MD simulations. Chemical insights into the arrangement of copolymer blocks that promote lower interfacial tension were mined using machine learning (ML) techniques. Overall, this work provides an efficient approach to solve design problems via fusion of simulations and ML and provides important groundwork for future experimental investigation of s-BCPs for various applications.

AB - Star block copolymers (s-BCPs) have potential applications as novel surfactants or amphiphiles for emulsification, compatibilization, chemical transformations, and separations. s-BCPs have chain architectures where three or more linear diblock copolymer arms comprised of two chemically distinct linear polymers, e.g., solvophobic and solvophilic chains, are covalently joined at one point. The chemical composition of each of the subunit polymer chains comprising the arms, their molecular weights, and the number of arms can be varied to tailor the surface and interfacial activity of these architecturally unique molecules. This makes identification of the optimal s-BCP design nontrivial as the total number of plausible s-BCP architectures is experimentally or computationally intractable. In this work, we use molecular dynamics (MD) simulations coupled with a reinforcement learning-based Monte Carlo tree search (MCTS) to identify s-BCP designs that minimize the interfacial tension between polar and nonpolar solvents. We first validate the MCTS approach for the design of small- and medium-sized s-BCPs and then use it to efficiently identify sequences of copolymer blocks for large-sized s-BCPs. The structural origins of interfacial tension in these systems are also identified by using the configurations obtained from MD simulations. Chemical insights into the arrangement of copolymer blocks that promote lower interfacial tension were mined using machine learning (ML) techniques. Overall, this work provides an efficient approach to solve design problems via fusion of simulations and ML and provides important groundwork for future experimental investigation of s-BCPs for various applications.

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Accelerated Sequence Design of Star Block Copolymers: An Unbiased Exploration Strategy via Fusion of Molecular Dynamics Simulations and Machine Learning

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