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Fuller-Rylenes: Paving the Way for Promising Acceptors.

Jiajing FengHuiting FuWei JiangAndong ZhangHwa Sook RyuYoung Woo HanYanming SunZhaohui Wang
Published in: ACS applied materials & interfaces (2020)
The hybridization of different acceptors remains a fertile ground awaiting exploration, to fully promote the properties of both components. The concept of this work is to exploit a new form of fuller-rylene hybrids as promising acceptors by integrating planar rylene dye and spherical fullerene for boosting the power conversion efficiency. The synthesis of the fuller-rylenes via a straightforward synthetic strategy by one-pot Pd-catalyzed cyclization can be scaled-up. Specifically, our strategy allows the supplements and enhancement of absorption in the visible region, much wider structural and electronic variations by installing R1 groups as well as decorating R2 on the perylene core at will, and good processability without compromising the superior characteristics of fullerene. Thus, bay-decorated fuller-rylene S-Fuller-PMI revealed a ground-breaking efficiency as high as 8.01%, even outperforming [6,6]-phenyl-C61-butyric acid methyl ester (PC61BM) as a parallel comparison (7.09%). Our exploration paves a new way for the design of high-efficiency acceptors, which are promising alternatives to PC61BM in photovoltaic devices.
Keyphrases
  • solar cells
  • high efficiency
  • single cell
  • room temperature
  • single molecule
  • quantum dots