化学空间
计算机科学
空格(标点符号)
有机半导体
质量(理念)
数码产品
漏斗
变形
纳米技术
生化工程
人工智能
材料科学
物理
药物发现
生物信息学
工程类
电气工程
生物
机械工程
光电子学
量子力学
操作系统
作者
Christian Künkel,Johannes T. Margraf,Ke Chen,Harald Oberhofer,Karsten Reuter
标识
DOI:10.1038/s41467-021-22611-4
摘要
The versatility of organic molecules generates a rich design space for organic semiconductors (OSCs) considered for electronics applications. Offering unparalleled promise for materials discovery, the vastness of this design space also dictates efficient search strategies. Here, we present an active machine learning (AML) approach that explores an unlimited search space through consecutive application of molecular morphing operations. Evaluating the suitability of OSC candidates on the basis of charge injection and mobility descriptors, the approach successively queries predictive-quality first-principles calculations to build a refining surrogate model. The AML approach is optimized in a truncated test space, providing deep methodological insight by visualizing it as a chemical space network. Significantly outperforming a conventional computational funnel, the optimized AML approach rapidly identifies well-known and hitherto unknown molecular OSC candidates with superior charge conduction properties. Most importantly, it constantly finds further candidates with highest efficiency while continuing its exploration of the endless design space.
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