Low-cost machine learning approach to the prediction of transition metal
phosphor excited state properties
- URL: http://arxiv.org/abs/2209.08595v1
- Date: Sun, 18 Sep 2022 16:24:07 GMT
- Title: Low-cost machine learning approach to the prediction of transition metal
phosphor excited state properties
- Authors: Gianmarco Terrones, Chenru Duan, Aditya Nandy, and Heather J. Kulik
- Abstract summary: Photoactive iridium complexes are of broad interest due to their applications ranging from lighting to photocatalysis.
We leverage low-cost machine learning (ML) models to predict the excited state properties of iridium complexes.
- Score: 0.4306143768014156
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Photoactive iridium complexes are of broad interest due to their applications
ranging from lighting to photocatalysis. However, the excited state property
prediction of these complexes challenges ab initio methods such as
time-dependent density functional theory (TDDFT) both from an accuracy and a
computational cost perspective, complicating high throughput virtual screening
(HTVS). We instead leverage low-cost machine learning (ML) models to predict
the excited state properties of photoactive iridium complexes. We use
experimental data of 1,380 iridium complexes to train and evaluate the ML
models and identify the best-performing and most transferable models to be
those trained on electronic structure features from low-cost density functional
theory tight binding calculations. Using these models, we predict the three
excited state properties considered, mean emission energy of phosphorescence,
excited state lifetime, and emission spectral integral, with accuracy
competitive with or superseding TDDFT. We conduct feature importance analysis
to identify which iridium complex attributes govern excited state properties
and we validate these trends with explicit examples. As a demonstration of how
our ML models can be used for HTVS and the acceleration of chemical discovery,
we curate a set of novel hypothetical iridium complexes and identify promising
ligands for the design of new phosphors.
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