TY - JOUR
T1 - Green-Solvent Processed Blade-Coating Organic Solar Cells with an Efficiency Approaching 19% Enabled by Alkyl-Tailored Acceptors
AU - Bai, Hairui
AU - Ma, Ruijie
AU - Su, Wenyan
AU - Peña, Top Archie Dela
AU - Li, Tengfei
AU - Tang, Lingxiao
AU - Yang, Jie
AU - Hu, Bin
AU - Wang, Yilin
AU - Bi, Zhaozhao
AU - Su, Yueling
AU - Wei, Qi
AU - Wu, Qiang
AU - Duan, Yuwei
AU - Li, Yuxiang
AU - Wu, Jiaying
AU - Ding, Zicheng
AU - Liao, Xunfan
AU - Huang, Yinjuan
AU - Gao, Chao
AU - Lu, Guanghao
AU - Li, Mingjie
AU - Zhu, Weiguo
AU - Li, Gang
AU - Fan, Qunping
AU - Ma, Wei
N1 - Publisher Copyright:
© 2023, The Author(s).
PY - 2023/12
Y1 - 2023/12
N2 - Power-conversion-efficiencies (PCEs) of organic solar cells (OSCs) in laboratory, normally processed by spin-coating technology with toxic halogenated solvents, have reached over 19%. However, there is usually a marked PCE drop when the blade-coating and/or green-solvents toward large-scale printing are used instead, which hampers the practical development of OSCs. Here, a new series of N-alkyl-tailored small molecule acceptors named YR-SeNF with a same molecular main backbone are developed by combining selenium-fused central-core and naphthalene-fused end-group. Thanks to the N-alkyl engineering, NIR-absorbing YR-SeNF series show different crystallinity, packing patterns, and miscibility with polymeric donor. The studies exhibit that the molecular packing, crystallinity, and vertical distribution of active layer morphologies are well optimized by introducing newly designed guest acceptor associated with tailored N-alkyl chains, providing the improved charge transfer dynamics and stability for the PM6:L8-BO:YR-SeNF-based OSCs. As a result, a record-high PCE approaching 19% is achieved in the blade-coating OSCs fabricated from a green-solvent o-xylene with high-boiling point. Notably, ternary OSCs offer robust operating stability under maximum-power-point tracking and well-keep > 80% of the initial PCEs for even over 400 h. Our alkyl-tailored guest acceptor strategy provides a unique approach to develop green-solvent and blade-coating processed high-efficiency and operating stable OSCs, which paves a way for industrial development.[Figure not available: see fulltext.]
AB - Power-conversion-efficiencies (PCEs) of organic solar cells (OSCs) in laboratory, normally processed by spin-coating technology with toxic halogenated solvents, have reached over 19%. However, there is usually a marked PCE drop when the blade-coating and/or green-solvents toward large-scale printing are used instead, which hampers the practical development of OSCs. Here, a new series of N-alkyl-tailored small molecule acceptors named YR-SeNF with a same molecular main backbone are developed by combining selenium-fused central-core and naphthalene-fused end-group. Thanks to the N-alkyl engineering, NIR-absorbing YR-SeNF series show different crystallinity, packing patterns, and miscibility with polymeric donor. The studies exhibit that the molecular packing, crystallinity, and vertical distribution of active layer morphologies are well optimized by introducing newly designed guest acceptor associated with tailored N-alkyl chains, providing the improved charge transfer dynamics and stability for the PM6:L8-BO:YR-SeNF-based OSCs. As a result, a record-high PCE approaching 19% is achieved in the blade-coating OSCs fabricated from a green-solvent o-xylene with high-boiling point. Notably, ternary OSCs offer robust operating stability under maximum-power-point tracking and well-keep > 80% of the initial PCEs for even over 400 h. Our alkyl-tailored guest acceptor strategy provides a unique approach to develop green-solvent and blade-coating processed high-efficiency and operating stable OSCs, which paves a way for industrial development.[Figure not available: see fulltext.]
KW - Alkyl-tailored guest acceptors
KW - Blade-coating
KW - Green solvent processing
KW - Organic solar cells
KW - Stability
UR - http://www.scopus.com/inward/record.url?scp=85175719595&partnerID=8YFLogxK
U2 - 10.1007/s40820-023-01208-0
DO - 10.1007/s40820-023-01208-0
M3 - Journal article
AN - SCOPUS:85175719595
SN - 2311-6706
VL - 15
JO - Nano-Micro Letters
JF - Nano-Micro Letters
IS - 1
M1 - 241
ER -