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Assessing conformer energies using electronic structure and machine learning methods
Author(s) -
Folmsbee Dakota,
Hutchison Geoffrey
Publication year - 2021
Publication title -
international journal of quantum chemistry
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.484
H-Index - 105
eISSN - 1097-461X
pISSN - 0020-7608
DOI - 10.1002/qua.26381
Subject(s) - maxima and minima , density functional theory , ab initio , coupled cluster , conformational isomerism , electronic structure , single point , cluster (spacecraft) , point (geometry) , statistical physics , molecule , molecular physics , physics , chemistry , computational chemistry , computer science , quantum mechanics , mathematics , geometry , computer simulation , mathematical analysis , mechanics , programming language
We have performed a large‐scale evaluation of current computational methods, including conventional small‐molecule force fields; semiempirical, density functional, ab initio electronic structure methods; and current machine learning (ML) techniques to evaluate relative single‐point energies. Using up to 10 local minima geometries across ~700 molecules, each optimized by B3LYP‐D3BJ with single‐point DLPNO‐CCSD(T) triple‐zeta energies, we consider over 6500 single points to compare the correlation between different methods for both relative energies and ordered rankings of minima. We find that the current ML methods have potential and recommend methods at each tier of the accuracy‐time tradeoff, particularly the recent GFN2 semiempirical method, the B97‐3c density functional approximation, and RI‐MP2 for accurate conformer energies. The ANI family of ML methods shows promise, particularly the ANI‐1ccx variant trained in part on coupled‐cluster energies. Multiple methods suggest continued improvements should be expected in both performance and accuracy.