Issue 12, 2020

Molecular generation targeting desired electronic properties via deep generative models

Abstract

As we seek to discover new functional materials, we need ways to explore the vast chemical space of precursor building blocks, not only generating large numbers of possible building blocks to investigate, but trying to find non-obvious options, that we might not suggest by chemical experience alone. Artificial intelligence techniques provide a possible avenue to generate large numbers of organic building blocks for functional materials, and can even do so from very small initial libraries of known building blocks. Specifically, we demonstrate the application of deep recurrent neural networks for the exploration of the chemical space of building blocks for a test case of donor–acceptor oligomers with specific electronic properties. The recurrent neural network learned how to produce novel donor–acceptor oligomers by trading off between selected atomic substitutions, such as halogenation or methylation, and molecular features such as the oligomer's size. The electronic and structural properties of the generated oligomers can be tuned by sampling from different subsets of the training database, which enabled us to enrich the library of donor–acceptors towards desired properties. We generated approximately 1700 new donor–acceptor oligomers with a recurrent neural network tuned to target oligomers with a HOMO–LUMO gap <2 eV and a dipole moment <2 Debye, which could have potential application in organic photovoltaics.

Graphical abstract: Molecular generation targeting desired electronic properties via deep generative models

Supplementary files

Article information

Article type
Paper
Submitted
18 Dec 2019
Accepted
04 Mar 2020
First published
09 Mar 2020
This article is Open Access
Creative Commons BY-NC license

Nanoscale, 2020,12, 6744-6758

Molecular generation targeting desired electronic properties via deep generative models

Q. Yuan, A. Santana-Bonilla, M. A. Zwijnenburg and K. E. Jelfs, Nanoscale, 2020, 12, 6744 DOI: 10.1039/C9NR10687A

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