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An Effective Method for Recovering Nonradiative Recombination Loss in Scalable Organic Solar Cells

Zhi Xing, Xiangchuan Meng, Rui Sun, Ting Hu, Zengqi Huang, Jie Min, Xiaotian Hu, Yiwang Chen

2020Advanced Functional Materials37 citationsDOI

Abstract

Abstract Regarded as a critical step in commercial applications, scalable printing technology has become a research frontier in the field of organic solar cells. However, inevitable efficiency loss always occurs in the lab‐to‐manufacturing translation due to the different fabrication processes. In fact, the decline of photovoltaic performance is mainly related to voltage loss, which is mainly affected by the diversity of phase separation morphology and the chemical structures of photoactive materials. Fullerene derivative indene‐C 60 bisadduct (ICBA) is introduced into a PBDB‐T‐2F:IT‐4F system to control the active layer morphology during blade‐coating process. Accordingly, as a symmetrical fullerene derivative, ICBA can regulate the crystallization tendency and molecular packing orientation and suppress charge carrier recombination. This ternary strategy overcomes the morphology issues caused by weaker shear impulse in blade‐coating process. Benefiting from the reduced nonradiative recombination loss, 1.05 cm 2 devices are fabricated by blade coating with a power conversion efficiency of 13.70%. This approach provides an effective support for recovering the voltage loss during scalable printing approaches.

Topics & Concepts

Materials scienceCoatingCrystallizationOptoelectronicsOrganic solar cellPhotoactive layerFullereneEnergy conversion efficiencyNanotechnologyChemical engineeringPolymer solar cellComposite materialPolymerOrganic chemistryChemistryEngineeringOrganic Electronics and PhotovoltaicsConducting polymers and applicationsPerovskite Materials and Applications