Retrospective on a decade of machine learning for chemical discovery

Lilienfeld, O. Anatole von; Burke, Kieron

doi:10.1038/s41467-020-18556-9

Cited by 154 publications

(128 citation statements)

References 29 publications

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“…5 The number of molecules predicted to have a local or global minima after 2Å. 6 BAND-NN regularly would not predict energies for geometries with a bond stretch of 2Å or greater.…”

Section: Resultsmentioning

confidence: 99%

Evaluation of Thermochemical Machine Learning for Potential Energy Curves and Geometry Optimization

2021

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While many machine learning methods, particularly deep neural networks, have been trained for density functional and quantum chemical energies and properties, the vast majority of these methods focus on single-point energies. In principle, such ML methods, once trained, o↵er thermochemical accuracy on par with density functional and wave function methods but at speeds comparable to traditional force fields or approximate semiempirical methods. So far, most e↵orts have focused on optimized equilibrium single-point energies and properties. In this work, we evaluate the accuracy of several leading ML methods across a range of bond potential energy curves and torsional potentials. Methods were trained on the existing ANI-1 training set, calculated using the !B97X / 6-31G(d) single points at non-equilibrium geometries. We find that across a range of small molecules, several methods o↵er both qualitative accuracy (e.g., correct minima, both repulsive and attractive bond regions, anharmonic shape, and single minima) and quantitative accuracy in terms of the mean absolute percent error near the minima. At the moment, ANI-2x, FCHL, and a new libmolgrid-based convolutional neural net show good performance.

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“…5 The number of molecules predicted to have a local or global minima after 2Å. 6 BAND-NN regularly would not predict energies for geometries with a bond stretch of 2Å or greater.…”

Section: Resultsmentioning

confidence: 99%

Evaluation of Thermochemical Machine Learning for Potential Energy Curves and Geometry Optimization

2021

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“…Two converging movements are responsible for the revolution. The first may be referred to as “data-intensive discovery” [ 1 ], “e-Science”, or “big data” [ 3 , 4 ], a movement wherein massive amounts of data are transformed into knowledge. This is attained with various computational methods, which increasingly engage ML techniques, in a movement characterized by a transition in which data move from a “passive” to an “active” role.…”

Section: Introductionmentioning

confidence: 99%

Big data and machine learning for materials science

et al. 2021

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Herein, we review aspects of leading-edge research and innovation in materials science that exploit big data and machine learning (ML), two computer science concepts that combine to yield computational intelligence. ML can accelerate the solution of intricate chemical problems and even solve problems that otherwise would not be tractable. However, the potential benefits of ML come at the cost of big data production; that is, the algorithms demand large volumes of data of various natures and from different sources, from material properties to sensor data. In the survey, we propose a roadmap for future developments with emphasis on computer-aided discovery of new materials and analysis of chemical sensing compounds, both prominent research fields for ML in the context of materials science. In addition to providing an overview of recent advances, we elaborate upon the conceptual and practical limitations of big data and ML applied to materials science, outlining processes, discussing pitfalls, and reviewing cases of success and failure.

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“…Machine learning (ML) has newfound relevance in quantum chemistry for accelerating simulations and providing predictions of ab initio quality. [14][15][16] Here, we leverage ML techniques and build an accurate and extensible ML model for phosphorescence energy that is enabled by its ability to account for electron localization associated with the spin transition.…”

Section: Introductionmentioning

confidence: 99%