Predicting Emission Spectra of Heteroleptic Iridium Complexes Using Artificial Chemical Intelligence

We report a deep learning-based approach to accurately predict the emission spectra of phosphorescent heteroleptic [Ir( ) ( )] complexes, enabling the rapid discovery of novel Ir(III) chromophores for diverse applications including organic light-emitting diodes and solar fuel cells. The deep learnin...

Full description

Saved in:
Bibliographic Details
Published in:Chemphyschem 2024-08, Vol.25 (16), p.e202400176
Main Authors: Pal, Yudhajit, Fiala, Tahoe A, Swords, Wesley B, Yoon, Tehshik P, Schmidt, J R
Format: Article
Language:English
Subjects:
Chromophores
Deep learning
Design of experiments
Emission spectra
Fuel cells
Graph neural networks
Iridium compounds
Light emitting diodes
Phosphorescence
Spectral emissivity
Wave functions
Wedges
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:We report a deep learning-based approach to accurately predict the emission spectra of phosphorescent heteroleptic [Ir( ) ( )] complexes, enabling the rapid discovery of novel Ir(III) chromophores for diverse applications including organic light-emitting diodes and solar fuel cells. The deep learning models utilize graph neural networks and other chemical features in architectures that reflect the inherent structure of the heteroleptic complexes, composed of and ligands, and are thus geared towards efficient training over the dataset. By leveraging experimental emission data, our models reliably predict the full emission spectra of these complexes across various emission profiles, surpassing the accuracy of conventional DFT and correlated wavefunction methods, while simultaneously achieving robustness to the presence of imperfect (noisy, low-quality) training spectra. We showcase the potential applications for these and related models for in silico prediction of complexes with tailored emission properties, as well as in "design of experiment" contexts to reduce the synthetic burden of high-throughput screening. In the latter case, we demonstrate that the models allow us to exploit a limited amount of experimental data to explore a wide range of chemical space, thus leveraging a modest synthetic effort.
ISSN:1439-4235
1439-7641
1439-7641
DOI:10.1002/cphc.202400176