Abstract
The ReaxFF reactive force-field approach has significantly extended the applicability of reactive molecular dynamics simulations to a wide range of material properties and processes. ReaxFF parameters are commonly trained to fit a predefined set of quantum-mechanical data, but it remains uncertain how accurately the quantities of interest are described when applied to complex chemical reactions. Here, we present a dynamic approach based on multiobjective genetic algorithm for the training of ReaxFF parameters and uncertainty quantification of simulated quantities of interest. ReaxFF parameters are trained by directly fitting reactive molecular dynamics trajectories against quantum molecular dynamics trajectories on the fly, where the Pareto optimal front for the multiple quantities of interest provides an ensemble of ReaxFF models for uncertainty quantification. Our in situ multiobjective genetic algorithm workflow achieves scalability by eliminating the file I/O bottleneck using interprocess communications. The in situ multiobjective genetic algorithm workflow has been applied to high-temperature sulfidation of MoO3 by H2S precursor, which is an essential reaction step for chemical vapor deposition synthesis of MoS2 layers. Our work suggests a new reactive molecular dynamics simulation approach for far-from-equilibrium chemical processes, which quantitatively reproduces quantum molecular dynamics simulations while providing error bars.
Highlights
The reactive molecular dynamics (RMD) method has enabled large-scale simulations of chemical events in complex materials involving multimillion atoms.[1,2] In particular, RMD simulations based on first principles-informed reactive force fields (ReaxFF)[3] describe chemical reactions through a bond-order/distance relationship that reflects each atom’s coordination change
We describe the optimization of ReaxFF parameters using in situ MOGA (iMOGA)
It is essential that the time evolution of those key reaction events by the quantum molecular dynamics (QMD) simulations be quantitatively reproduced by RMD simulations
Summary
The reactive molecular dynamics (RMD) method has enabled large-scale simulations of chemical events in complex materials involving multimillion atoms.[1,2] In particular, RMD simulations based on first principles-informed reactive force fields (ReaxFF)[3] describe chemical reactions (i.e., bond breakage and formation) through a bond-order/distance relationship that reflects each atom’s coordination change. In addition to such a well-established optimization technique, several ReaxFF optimization frameworks have been developed recently using multiobjective genetic algorithms (MOGA) and other evolutionary optimization methods.[6,7] QM data points in a training set include energies of small clusters (e.g., full bond dissociation, angle distortion and torsion energies) and reaction energies/
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