Journal
INTERNATIONAL JOURNAL OF QUANTUM CHEMISTRY
Volume 115, Issue 16, Pages 1074-1083Publisher
WILEY
DOI: 10.1002/qua.24836
Keywords
ab initio molecular dynamics; accelerate; machine learning; fingerprint; adaptive
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Funding
- Office of Naval Research [N00014-14-1-0098]
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Quantum mechanics-based ab initio molecular dynamics (MD) simulation schemes offer an accurate and direct means to monitor the time evolution of materials. Nevertheless, the expensive and repetitive energy and force computations required in such simulations lead to significant bottlenecks. Here, we lay the foundations for an accelerated ab initio MD approach integrated with a machine learning framework. The proposed algorithm learns from previously visited configurations in a continuous and adaptive manner on-the-fly, and predicts (with chemical accuracy) the energies and atomic forces of a new configuration at a minuscule fraction of the time taken by conventional ab initio methods. Key elements of this new accelerated ab initio MD paradigm include representations of atomic configurations by numerical fingerprints, a learning algorithm to map the fingerprints to the properties, a decision engine that guides the choice of the prediction scheme, and requisite amount of ab initio data. The performance of each aspect of the proposed scheme is critically evaluated for Al in several different chemical environments. This work has enormous implications beyond ab initio MD acceleration. It can also lead to accelerated structure and property prediction schemes, and accurate force fields. (c) 2014 Wiley Periodicals, Inc.
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