Finding the Right Bricks for Molecular Legos: A Data Mining Approach to Organic Semiconductor Design

C Kunkel and C Schober and JT Margraf and K Reuter and H Oberhofer, CHEMISTRY OF MATERIALS, 31, 969-978 (2019).

DOI: 10.1021/acs.chemmater.8b04436

Improving charge carrier mobilities in organic semiconductors is a challenging task that has hitherto primarily been tackled by empirical structural tuning of promising core compounds. Knowledge-based methods can greatly accelerate such local exploration, while a systematic analysis of large chemical databases can point toward promising design strategies. Here, we demonstrate such data mining by clustering an in- house database of >64,000 organic molecular crystals for which two charge-transport descriptors, the electronic coupling and the reorganization energy, have been calculated from first principles. The clustering is performed according to the Bemis-Murcko scaffolds of the constituting molecules and according to the side groups with which these molecular backbones are functionalized. In both cases, we obtain statistically significant structure-property relationships with certain scaffolds (side groups) consistently leading to favorable charge- transport properties. Functionalizing promising scaffolds with favorable side groups results in engineered molecular crystals for which we indeed compute improved charge-transport properties.

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