Resolving Transition Metal Chemical Space: Feature Selection for Machine Learning and Structure–Property Relationships
Author(s)
Janet, Jon Paul; Kulik, Heather J.
DownloadFS_draft_v8_resub_nomark_OA.pdf (3.290Mb)
Publisher Policy
Publisher Policy
Article is made available in accordance with the publisher's policy and may be subject to US copyright law. Please refer to the publisher's site for terms of use.
Terms of use
Metadata
Show full item recordAbstract
Machine learning (ML) of quantum mechanical properties shows promise for accelerating chemical discovery. For transition metal chemistry where accurate calculations are computationally costly and available training data sets are small, the molecular representation becomes a critical ingredient in ML model predictive accuracy. We introduce a series of revised autocorrelation functions (RACs) that encode relationships of the heuristic atomic properties (e.g., size, connectivity, and electronegativity) on a molecular graph. We alter the starting point, scope, and nature of the quantities evaluated in standard ACs to make these RACs amenable to inorganic chemistry. On an organic molecule set, we first demonstrate superior standard AC performance to other presently available topological descriptors for ML model training, with mean unsigned errors (MUEs) for atomization energies on set-aside test molecules as low as 6 kcal/mol. For inorganic chemistry, our RACs yield 1 kcal/mol ML MUEs on set-aside test molecules in spin-state splitting in comparison to 15–20× higher errors for feature sets that encode whole-molecule structural information. Systematic feature selection methods including univariate filtering, recursive feature elimination, and direct optimization (e.g., random forest and LASSO) are compared. Random-forest- or LASSO-selected subsets 4–5× smaller than the full RAC set produce sub- to 1 kcal/mol spin-splitting MUEs, with good transferability to metal–ligand bond length prediction (0.004–5 Å MUE) and redox potential on a smaller data set (0.2–0.3 eV MUE). Evaluation of feature selection results across property sets reveals the relative importance of local, electronic descriptors (e.g., electronegativity, atomic number) in spin-splitting and distal, steric effects in redox potential and bond lengths.
Date issued
2017-11Department
Massachusetts Institute of Technology. Department of Chemical EngineeringJournal
Journal of Physical Chemistry A
Publisher
American Chemical Society (ACS)
Citation
Janet, Jon Paul and Heather J. Kulik. "Resolving Transition Metal Chemical Space: Feature Selection for Machine Learning and Structure–Property Relationships." Journal of Physical Chemistry A 121, 46 (November 2017): 8939-8954 © 2017 American Chemical Society
Version: Author's final manuscript
ISSN
1089-5639
1520-5215