# Machine Learning Prediction of Accurate Atomization Energies of Organic   Molecules from Low-Fidelity Quantum Chemical Calculations

**Authors:** Logan Ward, Ben Blaiszik, Ian Foster, Rajeev S. Assary, Badri, Narayanan, Larry Curtiss

arXiv: 1906.03233 · 2022-02-15

## TL;DR

This paper demonstrates machine learning models that accurately predict high-level quantum chemical atomization energies of organic molecules from low-fidelity calculations, significantly reducing computational costs.

## Contribution

The study introduces ML models that learn to correct low-fidelity quantum calculations to high-accuracy energies, enabling efficient predictions for larger molecules.

## Key findings

- Achieved mean absolute error of 0.005 eV for molecules with fewer than 9 heavy atoms.
- Predicted energies with 0.012 eV MAE for molecules with 10-14 heavy atoms.
- Provided accessible web interface for energy predictions.

## Abstract

Recent studies illustrate how machine learning (ML) can be used to bypass a core challenge of molecular modeling: the tradeoff between accuracy and computational cost. Here, we assess multiple ML approaches for predicting the atomization energy of organic molecules. Our resulting models learn the difference between low-fidelity, B3LYP, and high-accuracy, G4MP2, atomization energies, and predict the G4MP2 atomization energy to 0.005 eV (mean absolute error) for molecules with less than 9 heavy atoms and 0.012 eV for a small set of molecules with between 10 and 14 heavy atoms. Our two best models, which have different accuracy/speed tradeoffs, enable the efficient prediction of G4MP2-level energies for large molecules and are available through a simple web interface.

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Source: https://tomesphere.com/paper/1906.03233