Understanding the Nonradiative Charge Recombination in Organic Photovoltaics: From Molecule to Device

Organic photovoltaics (OPVs) have made significant strides with efficiencies now exceeding 20%, positioning them as potential competitors to inorganic solar technologies. One of the most critical challenges toward this goal is the severe open-circuit voltage (Voc) loss caused by the nonradiative charge recombination (NRCR). Herein, this review comprehensively summarizes the NRCR mechanisms and suppression techniques of OPVs across various scales from molecule to device. Specifically, the origins of NRCR in a single molecule are first summarized, and molecular design principles toward high photoluminescence quantum yield are reviewed following the Marcus theory. Next, the effect of aggregation on NRCR is reviewed, as well as the molecular and processing strategies to modulate the film packing for NRCR suppression. Furthermore, the progresses in the avoidance of nonradiative loss pathways mediated by charge transfer states and triplet states in donor:acceptor bulk heterojunctions are tracked. Besides, the interfacial optimization and device structure design to maximize the electroluminescent quantum efficiency are presented. Finally, several potential pathways toward curtailing NRCR for high-performance OPVs are outlined. Therefore, this review shows an insightful perspective to understand and mitigate the NRCR at multi-scales, and is poised to provide a clear roadmap for the next breakthrough of OPVs. This review summarizes the nonradiative charge recombination (NRCR) pathways and suppression strategies across various scales in organic photovoltaics (OPVs), spanning from the molecular to the device level. Several potential pathways toward curtailing NRCR for high-performance OPVs are highlighted. Therefore, this review is poised to provide a clear roadmap for the next breakthrough of OPVs. image