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Assessment and Validation of Machine Learning Methods for Predicting Molecular Atomization Energies

Overview
Journal J Chem Theory Comput
Publisher American Chemical Society
Specialties Biochemistry
Chemistry
Date 2015 Nov 20
PMID 26584096
Citations 85
Authors
Katja Hansen
Gregoire Montavon
Franziska Biegler
Siamac Fazli
Matthias Rupp
Matthias Scheffler
O Anatole von Lilienfeld
Alexandre Tkatchenko
Klaus-Robert Muller
Affiliations
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Abstract

The accurate and reliable prediction of properties of molecules typically requires computationally intensive quantum-chemical calculations. Recently, machine learning techniques applied to ab initio calculations have been proposed as an efficient approach for describing the energies of molecules in their given ground-state structure throughout chemical compound space (Rupp et al. Phys. Rev. Lett. 2012, 108, 058301). In this paper we outline a number of established machine learning techniques and investigate the influence of the molecular representation on the methods performance. The best methods achieve prediction errors of 3 kcal/mol for the atomization energies of a wide variety of molecules. Rationales for this performance improvement are given together with pitfalls and challenges when applying machine learning approaches to the prediction of quantum-mechanical observables.

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