Abstract

We present a computational workflow based on quantum chemical calculations and generative models based on deep neural networks for the discovery of novel materials. We apply the developed workflow to search for molecules suitable for the fusion of triplet-triplet excitations (triplet-triplet fusion, TTF) in blue OLED devices. By applying generative machine learning models, we have been able to pinpoint the most promising regions of the chemical space for further exploration. Another neural network based on graph convolutions was trained to predict excitation energies; with this network, we estimate the alignment of energy levels and filter molecules before running time-consuming quantum chemical calculations. We present a comprehensive computational evaluation of several generative models, choosing a modification of the Junction Tree VAE (JT-VAE) as the best one in this application. The proposed approach can be useful for computer-aided design of materials with energy level alignment favorable for efficient energy transfer, triplet harvesting, and exciton fusion processes, which are crucial for the development of the next generation OLED materials.

Highlights

  • Operation of organic light emitting and photovoltaic devices can be greatly improved by utilizing the triplet–triplet fusion (TTF) process, when two triplet excitons of low energy merge into one singlet exciton of higher energy (Gray et al, 2014)

  • We have investigated the performance of our implementation of the Junction Tree variational autoencoder (VAE) (JT-VAE) model and three well-known baseline models, namely:

  • Based on the above analysis, we suggest the JT-VAE model with seeded sampling as the best generative model for the discovery of realistic candidates for deep blue OLED applications

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Summary

Introduction

Operation of organic light emitting and photovoltaic devices can be greatly improved by utilizing the triplet–triplet fusion (TTF) process, when two triplet excitons of low energy merge into one singlet exciton of higher energy (Gray et al, 2014). Despite some successes in the discovery of TTF materials (Kondakov, 2015), their number is still limited, the main reason being strict requirements on the alignment of the lowest singlet and triplet energy levels that is difficult to satisfy by randomly picking a compound (Gómez-Bombarelli et al, 2016; Wang et al, 2020). Any core requires certain chemical modifications to become a real-life TTF material due to technology-related reasons; these modifications may be needed to increase solubility, prevent undesired aggregation, or reduce photochemical degradation. In such cases, one should be careful not to spoil a promising

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