Wu Jianchang, Torresi Luca, Hu ManMan, Reiser Patrick, Zhang Jiyun, Rocha-Ortiz Juan S, Wang Luyao, Xie Zhiqiang, Zhang Kaicheng, Park Byung-Wook, Barabash Anastasia, Zhao Yicheng, Luo Junsheng, Wang Yunuo, Lüer Larry, Deng Lin-Long, Hauch Jens A, Guldi Dirk M, Pérez-Ojeda M Eugenia, Seok Sang Il, Friederich Pascal, Brabec Christoph J
Forschungszentrum Jülich GmbH, Helmholtz-Institute Erlangen-Nürnberg (HI-ERN), Erlangen, Germany.
Faculty of Engineering, Department of Material Science, Materials for Electronics and Energy Technology (i-MEET), Friedrich-Alexander-Universität Erlangen-Nürnberg (FAU), Erlangen, Germany.
Science. 2024 Dec 13;386(6727):1256-1264. doi: 10.1126/science.ads0901. Epub 2024 Dec 12.
The inverse design of tailored organic molecules for specific optoelectronic devices of high complexity holds an enormous potential but has not yet been realized. Current models rely on large data sets that generally do not exist for specialized research fields. We demonstrate a closed-loop workflow that combines high-throughput synthesis of organic semiconductors to create large datasets and Bayesian optimization to discover new hole-transporting materials with tailored properties for solar cell applications. The predictive models were based on molecular descriptors that allowed us to link the structure of these materials to their performance. A series of high-performance molecules were identified from minimal suggestions and achieved up to 26.2% (certified 25.9%) power conversion efficiency in perovskite solar cells.
为高复杂度的特定光电器件量身定制有机分子的逆向设计具有巨大潜力,但尚未实现。当前模型依赖于大数据集,而这些数据集在专业研究领域通常并不存在。我们展示了一种闭环工作流程,该流程将有机半导体的高通量合成与贝叶斯优化相结合,以创建大数据集并发现具有定制特性的新型空穴传输材料用于太阳能电池应用。预测模型基于分子描述符,使我们能够将这些材料的结构与其性能联系起来。通过最少的建议就识别出了一系列高性能分子,这些分子在钙钛矿太阳能电池中实现了高达26.2%(认证值为25.9%)的功率转换效率。
