Structural engineering of porphyrin-based small molecules as donors for efficient organic solar cells

Porphyrin-based small molecules as donors have long been ignored in bulky heterojunction organic solar cells due to their unfavorable aggregation and the low charge mobility. With the aim of striking a delicate balance between molecular design, morphology, interfacial layer and device fabrication to...

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Veröffentlicht in:	Chemical science (Cambridge) 2016-01, Vol.7 (7), p.431-437
Hauptverfasser:	Wang, Hongda, Xiao, Liangang, Yan, Lei, Chen, Song, Zhu, Xunjin, Peng, Xiaobin, Wang, Xingzhu, Wong, Wai-Kwok, Wong, Wai-Yeung
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Sprache:	eng
Schlagworte:	Chemistry Devices Energy conversion efficiency Heterojunctions Photovoltaic cells Porphyrins Solar cells Stacking Structural engineering
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container_title	Chemical science (Cambridge)
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creator	Wang, Hongda Xiao, Liangang Yan, Lei Chen, Song Zhu, Xunjin Peng, Xiaobin Wang, Xingzhu Wong, Wai-Kwok Wong, Wai-Yeung
description	Porphyrin-based small molecules as donors have long been ignored in bulky heterojunction organic solar cells due to their unfavorable aggregation and the low charge mobility. With the aim of striking a delicate balance between molecular design, morphology, interfacial layer and device fabrication to maximize the power conversion efficiency (PCE) of organic solar cells, three comparable porphyrin-based small molecules with an acceptor-donor-acceptor configuration have been developed for use as donor materials in solution processed small molecule bulk heterojunction organic solar cells. In these molecules, electron-deficient 3-ethylrhodanine is introduced into the electron-rich porphyrin core through 5,15-bis(phenylethynyl) linkers. Structural engineering with 10,20-bis(2-hexylnonyl) aliphatic peripheral substituent on the porphyrin core, instead of the aromatic substituents such as 10,20-bis[3,5-di(dodecyloxyl)phenyl], and 10,20-bis(4-dodecyloxylphenyl), can simultaneously facilitate stronger intermolecular π-π stacking and higher charge transfer mobility in the film, leading to a maximum PCE of 7.70% in a conventional device. The inverted devices have also been demonstrated to have long-term ambient stability and a comparable PCE of 7.55%. Three A-D-A porphyrin-based small molecules are employed as donors in bulky heterojunction organic solar cells. Striking a delicate balance between solubility, morphology and device fabrication, leads to PCEs of up to 7.7%.
doi_str_mv	10.1039/c5sc04783h
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With the aim of striking a delicate balance between molecular design, morphology, interfacial layer and device fabrication to maximize the power conversion efficiency (PCE) of organic solar cells, three comparable porphyrin-based small molecules with an acceptor-donor-acceptor configuration have been developed for use as donor materials in solution processed small molecule bulk heterojunction organic solar cells. In these molecules, electron-deficient 3-ethylrhodanine is introduced into the electron-rich porphyrin core through 5,15-bis(phenylethynyl) linkers. Structural engineering with 10,20-bis(2-hexylnonyl) aliphatic peripheral substituent on the porphyrin core, instead of the aromatic substituents such as 10,20-bis[3,5-di(dodecyloxyl)phenyl], and 10,20-bis(4-dodecyloxylphenyl), can simultaneously facilitate stronger intermolecular π-π stacking and higher charge transfer mobility in the film, leading to a maximum PCE of 7.70% in a conventional device. The inverted devices have also been demonstrated to have long-term ambient stability and a comparable PCE of 7.55%. Three A-D-A porphyrin-based small molecules are employed as donors in bulky heterojunction organic solar cells. 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The inverted devices have also been demonstrated to have long-term ambient stability and a comparable PCE of 7.55%. Three A-D-A porphyrin-based small molecules are employed as donors in bulky heterojunction organic solar cells. 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subjects	Chemistry Devices Energy conversion efficiency Heterojunctions Photovoltaic cells Porphyrins Solar cells Stacking Structural engineering
title	Structural engineering of porphyrin-based small molecules as donors for efficient organic solar cells
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