Fan B, Zeng Z, Zhong W, Ying L, Zhang D, Li M, Peng F, Li N, Huang F, Cao Y (2019)
Publication Type: Journal article
Publication year: 2019
Pages Range: 2466-2472
DOI: 10.1021/acsenergylett.9b01447
The successful demonstration of high-performance organic solar cells (OSCs) on a relatively large area is vital for their industrial viability and future application. When the device area is enlarged from several mm2 to the scale of >1 cm2, critical losses caused by film inhomogeneity or defects in the photoactive layer strongly restrict the performance and reproducibility of OSCs. In this work, we demonstrate that through delicate optimization of a photoactive layer and minimization of optoelectronic losses, an impressive external quantum efficiency maximum up to 88% and an internal quantum efficiency peak of 97% are achieved for nonfullerene OSCs. Further incorporating fullerene as the third component into the photoactive layer optimizes the microstructure morphology, enabling large-scale devices with an area of >1.1 cm2, surpassing the 15% efficiency milestone. The exciting results demonstrated in this work highlight the strategic priority to minimize losses through both materials and electronic engineering toward high-performance large-area OSCs.
APA:
Fan, B., Zeng, Z., Zhong, W., Ying, L., Zhang, D., Li, M.,... Cao, Y. (2019). Optimizing Microstructure Morphology and Reducing Electronic Losses in 1 cm2 Polymer Solar Cells to Achieve Efficiency over 15%. ACS Energy Letters, 2466-2472. https://doi.org/10.1021/acsenergylett.9b01447
MLA:
Fan, Baobing, et al. "Optimizing Microstructure Morphology and Reducing Electronic Losses in 1 cm2 Polymer Solar Cells to Achieve Efficiency over 15%." ACS Energy Letters (2019): 2466-2472.
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