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Forecasting molecular dynamics energetics of polymers in solution from supervised machine learning.
James Andrews1,2, Olga Gkountouna2, Estela Blaisten-Barojas1,2
1Center for Simulation and Modeling, George Mason University Fairfax Virginia 22030 USA blaisten@gmu.edu.
Recurrent neural networks (RNNs) like ERNN, LSTM, and GRU can accurately model system energetics but struggle with long-term forecasting. An enhanced in silico protocol improves predictions for macromolecular aggregates in solution.
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Area of Science:
- Computational Chemistry and Materials Science
- Machine Learning Applications in Science
Background:
- Machine learning, particularly neural networks, is increasingly used for analyzing chemical and physical systems.
- Predicting kinetics and dynamics using machine learning remains less explored compared to structure and energetics.
- Recurrent neural network (RNN) architectures are suitable for time-series data common in molecular simulations.
Purpose of the Study:
- To evaluate the performance of three RNN architectures (ERNN, LSTM, GRU) in reproducing and forecasting the energetics of a macromolecular aggregate in solution.
- To develop an improved in silico protocol for more reliable energetics forecasting in complex molecular systems.
Main Methods:
- Training and testing ERNN, LSTM, and GRU models on a large time series dataset of potential and interaction energies from molecular dynamics simulations.
- Developing a novel in silico protocol involving extraction of time patterns and ensemble modeling to enhance forecasting accuracy.
- Analyzing the ability of models to reproduce time series and forecast energetics with appropriate statistical distributions.
Main Results:
- The investigated RNN architectures excellently reproduced the time series data of macromolecular aggregate energetics.
- Forecasting capabilities for short-term and long-term energetics were limited, showing deviations in statistical distributions.
- The proposed in silico protocol significantly improved energetics forecasts, generating a band of time series consistent with simulation fluctuations.
Conclusions:
- While standard RNNs effectively model current energetics, an ensemble-based in silico protocol enhances their forecasting utility for solvated macromolecular aggregates.
- This data-driven protocol offers valuable insights into the system's future energetics, aiding decisions on simulation continuation.
- The approach expands the application of supervised machine learning as a decision-making tool in scientific simulations and materials design.