Abstract
Tandem organic solar cells can potentially drastically improve the PCE over single-junction devices. However, there is limited research on device development and often only ca. 1% improvement over single-junction devices. Because of the complex nature of organic material compatibility and properties, such as energy-level alignment and maximizing absorption spectra, and the vastness of chemical space, computational guidance is vital. The first part of this work uses a new data set of 1,225 donor/non-fullerene acceptor (NFA) pairs containing 1,001 unique pairs, one of the largest to date, to train an ensemble machine learning model to predict device efficiency (RMSE =1.60 +/- 0.14%). Next, a series of genetic algorithms (GA) are used to discover high-performing NFAs and polymer donors, and then combinations of them for potential high-efficiency tandem cells. Interesting design motifs show up in high-performing NFAs, such as diphenylamine substituents on the core and 3D terminal groups. The donor polymers from the GA reveal that it may be beneficial to arrange the monomers as a small-block copolymer instead of the common alternating copolymer. The GAs for selection of tandem cell materials successfully find material combinations, that when in a device together, have strong absorption across the entire visible-near-IR spectrum. Computational guidance is critical for the selection of tandem OSC materials, with genetic algorithms proving a highly successful technique.
Supplementary materials
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Supporting Information
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Details on performance of the machine learning models on the full dataset, common core and terminal units from the top candidates from the GA searches.
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Supplementary weblinks
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GitHub repository
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The machine learning models, genetic algorithms, and the data that supports the findings of this study are openly available
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