Improved photovoltaic performance and robustness of all-polymer solar cells enabled by a polyfullerene guest acceptor

Han Yu; Yan Wang; Xinhui Zou; Junli Yin; Xiaoyu Shi; Yuhao Li; Heng Zhao; Lingyuan Wang; Ho Ming Ng; Bosen Zou; Xinhui Lu; Kam Sing Wong; Wei Ma; Zonglong Zhu; He Yan; Shangshang Chen

doi:10.1038/s41467-023-37738-9

Improved photovoltaic performance and robustness of all-polymer solar cells enabled by a polyfullerene guest acceptor

Han Yu, Yan Wang, Xinhui Zou, Junli Yin, Xiaoyu Shi, Yuhao Li, Heng Zhao, Lingyuan Wang, Ho Ming Ng, Bosen Zou, Xinhui Lu, Kam Sing Wong^*, Wei Ma, Zonglong Zhu^*, He Yan^*, Shangshang Chen^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

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Abstract

Fullerene acceptors typically possess excellent electron-transporting properties and can work as guest components in ternary organic solar cells to enhance the charge extraction and efficiencies. However, conventional fullerene small molecules typically suffer from undesirable segregation and dimerization, thus limiting their applications in organic solar cells. Herein we report the use of a poly(fullerene-alt-xylene) acceptor (PFBO-C12) as guest component enables a significant efficiency increase from 16.9% for binary cells to 18.0% for ternary all-polymer solar cells. Ultrafast optic and optoelectronic studies unveil that PFBO-C12 can facilitate hole transfer and suppress charge recombination. Morphological investigations show that the ternary blends maintain a favorable morphology with high crystallinity and smaller domain size. Meanwhile, the introduction of PFBO-C12 reduces voltage loss and enables all-polymer solar cells with excellent light stability and mechanical durability in flexible devices. This work demonstrates that introducing polyfullerenes as guest components is an effective approach to achieving highly efficient ternary all-polymer solar cells with good stability and mechanical robustness. © The Author(s) 2023.

Original language	English
Article number	2323
Journal	Nature Communications
Volume	14
Online published	22 Apr 2023
DOIs	https://doi.org/10.1038/s41467-023-37738-9
Publication status	Published - 2023

Funding

S.C. thanks to the support from the National Natural Science Foundation of China (No. 020513004026) and Fundamental Research Funds for the Central University (grant nos. 020514380274 and 020514380284). H. Yan appreciates the support from the National Key Research and Development Program of China (No. 2019YFA0705900) funded by MOST, the Basic and Applied Research Major Program of Guangdong Province (No. 2019B030302007), National Natural Science Foundation of China (NSFC, No. 22075057), the Shen Zhen Technology and Innovation Commission through (Shenzhen Fundamental Research Program, JCYJ20200109140801751), the Hong Kong Research Grants Council (research fellow scheme RFS2021-6S05, RIF project R6021-18, CRF project C6023-19G, GRF project 16310019, 16310020, 16309221, 16309822), Hong Kong Innovation and Technology Commission (ITCCNERC14SC01) and Foshan-HKUST (Project No. FSUST19-CAT0202), Zhongshan Municipal Bureau of Science and Technology (No. ZSST20SC02) and Tencent Xplorer Prize.

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abstract = "Fullerene acceptors typically possess excellent electron-transporting properties and can work as guest components in ternary organic solar cells to enhance the charge extraction and efficiencies. However, conventional fullerene small molecules typically suffer from undesirable segregation and dimerization, thus limiting their applications in organic solar cells. Herein we report the use of a poly(fullerene-alt-xylene) acceptor (PFBO-C12) as guest component enables a significant efficiency increase from 16.9% for binary cells to 18.0% for ternary all-polymer solar cells. Ultrafast optic and optoelectronic studies unveil that PFBO-C12 can facilitate hole transfer and suppress charge recombination. Morphological investigations show that the ternary blends maintain a favorable morphology with high crystallinity and smaller domain size. Meanwhile, the introduction of PFBO-C12 reduces voltage loss and enables all-polymer solar cells with excellent light stability and mechanical durability in flexible devices. This work demonstrates that introducing polyfullerenes as guest components is an effective approach to achieving highly efficient ternary all-polymer solar cells with good stability and mechanical robustness. {\textcopyright} The Author(s) 2023.",

author = "Han Yu and Yan Wang and Xinhui Zou and Junli Yin and Xiaoyu Shi and Yuhao Li and Heng Zhao and Lingyuan Wang and Ng, {Ho Ming} and Bosen Zou and Xinhui Lu and Wong, {Kam Sing} and Wei Ma and Zonglong Zhu and He Yan and Shangshang Chen",

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journal = "Nature Communications",

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T1 - Improved photovoltaic performance and robustness of all-polymer solar cells enabled by a polyfullerene guest acceptor

AU - Yu, Han

AU - Wang, Yan

AU - Zou, Xinhui

AU - Yin, Junli

AU - Shi, Xiaoyu

AU - Li, Yuhao

AU - Zhao, Heng

AU - Wang, Lingyuan

AU - Ng, Ho Ming

AU - Zou, Bosen

AU - Lu, Xinhui

AU - Wong, Kam Sing

AU - Ma, Wei

AU - Zhu, Zonglong

AU - Yan, He

AU - Chen, Shangshang

PY - 2023

Y1 - 2023

N2 - Fullerene acceptors typically possess excellent electron-transporting properties and can work as guest components in ternary organic solar cells to enhance the charge extraction and efficiencies. However, conventional fullerene small molecules typically suffer from undesirable segregation and dimerization, thus limiting their applications in organic solar cells. Herein we report the use of a poly(fullerene-alt-xylene) acceptor (PFBO-C12) as guest component enables a significant efficiency increase from 16.9% for binary cells to 18.0% for ternary all-polymer solar cells. Ultrafast optic and optoelectronic studies unveil that PFBO-C12 can facilitate hole transfer and suppress charge recombination. Morphological investigations show that the ternary blends maintain a favorable morphology with high crystallinity and smaller domain size. Meanwhile, the introduction of PFBO-C12 reduces voltage loss and enables all-polymer solar cells with excellent light stability and mechanical durability in flexible devices. This work demonstrates that introducing polyfullerenes as guest components is an effective approach to achieving highly efficient ternary all-polymer solar cells with good stability and mechanical robustness. © The Author(s) 2023.

AB - Fullerene acceptors typically possess excellent electron-transporting properties and can work as guest components in ternary organic solar cells to enhance the charge extraction and efficiencies. However, conventional fullerene small molecules typically suffer from undesirable segregation and dimerization, thus limiting their applications in organic solar cells. Herein we report the use of a poly(fullerene-alt-xylene) acceptor (PFBO-C12) as guest component enables a significant efficiency increase from 16.9% for binary cells to 18.0% for ternary all-polymer solar cells. Ultrafast optic and optoelectronic studies unveil that PFBO-C12 can facilitate hole transfer and suppress charge recombination. Morphological investigations show that the ternary blends maintain a favorable morphology with high crystallinity and smaller domain size. Meanwhile, the introduction of PFBO-C12 reduces voltage loss and enables all-polymer solar cells with excellent light stability and mechanical durability in flexible devices. This work demonstrates that introducing polyfullerenes as guest components is an effective approach to achieving highly efficient ternary all-polymer solar cells with good stability and mechanical robustness. © The Author(s) 2023.

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Improved photovoltaic performance and robustness of all-polymer solar cells enabled by a polyfullerene guest acceptor

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CRF: Developing Non-fullerence Organic Solar Cells with Small Photovoltage Loss

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Improved photovoltaic performance and robustness of all-polymer solar cells enabled by a polyfullerene guest acceptor

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CRF: Developing Non-fullerence Organic Solar Cells with Small Photovoltage Loss

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