Thermoplastic Elastomer Tunes Phase Structure and Promotes Stretchability of High‐Efficiency Organic Solar Cells

Peng, Zhongxiang; Xian, Kaihu; Cui, Yong; Qi, Qingchun; Liu, Junwei; Xu, Ye; Chai, Yubo; Yang, Chunming; Hou, Jianhui; Geng, Yanhou; Ye, Long

doi:10.1002/adma.202106732

Cited by 133 publications

(144 citation statements)

References 77 publications

(122 reference statements)

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“…Ye and coworkers comprehensively investigated the influence of SEBS (polystyrene-blockpoly(ethylene-ran-butylene)-block-polystyrene) in different BHJ blended systems. [13] They demonstrated that the incorporation of thermoplastic elastomers in the BHJ systems was a universal strategy to improve the stretchability, reduce the elastic modulus, and maintain the photovoltaic performance. Moreover, the changes in mechanical and photovoltaic properties have been ascribed to the morphology evolutions of the composite systems.…”

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confidence: 99%

Insulating Polymers as Additives to Bulk‐Heterojunction Organic Solar Cells: The Effect of Miscibility

et al. 2021

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Adding insulating polymers to conjugated polymers is an efficient strategy to tailor their mechanical properties for flexible organic electronics. In this work, we selected two insulating polymers as additives for high‐performance photoactive layers and investigated the mechanical and photovoltaic properties in organic solar cells (OSCs). The insulating polymers were found to reduce the electron mobilities in the photoactive layers, and hence the power conversion efficiencies were significantly decreased. More importantly, we found that the insulating polymers exhibited negative effect on the mechanical properties of the photoactive layers, with reduced Young's modulus and low crack onset strains. Further studies revealed that the insulating polymers had poor miscibility with the photoactive layers, providing large domains and more cavities in blend thin films, which act as negative effect for the tensile test. The studies indicate that rational selection of insulating polymers, especially enhancing the non‐covalent interaction with the photoactive layers, will be critically important for the stretchable OSCs.

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confidence: 99%

Insulating Polymers as Additives to Bulk‐Heterojunction Organic Solar Cells: The Effect of Miscibility

et al. 2021

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“…Insertion of insulating breaking spacers (e.g., alkyls) to the backbones of conjugated polymers has been provided as a means to address the low ductility of Y6-based polymer acceptors. Besides, systematically characterizing the mechanical properties [104][105][106][107] of these polymer donors and acceptors might aid in the development of flexible and stretchable all-PSCs.…”

Section: Discussionmentioning

confidence: 99%

Eco‐friendly solution processing of all‐polymer solar cells: Recent advances and future perspective

Xiong

Zhang

2021

Journal of Polymer Science

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All-polymer solar cells (all-PSCs) exhibit great potentials in commercial applications. All-PSCs have observed steady performance gains with power conversion efficiency now reaching over 17% in the open literature. However, the current processing of all-PSCs relies predominantly on toxic, chlorinated solvents in moisture-free environments, representing a significant barrier for their commercialization due to the added costs to handle and dispose of such solvents. There is thus an urgent need for safe, environmentally benign, and sustainable ink-based processing methods to produce all-PSC devices reliably and reproducibly in ambient air. In this perspective, fundamental insights on the interplay between all-polymer blend morphologies and eco-friendly solvents are provided. Also, we discuss the recent successes of the green processing methods to manipulate the photoactive morphologies for high-efficiency all-PSCs. In the end, we provide an outlook on future challenges and opportunities of eco-friendly solvents processed all-PSCs for large-scale manufacturing.

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“…The film morphology of polymer blends not only affects the PCE of All-PSCs but also closely determines their mechanical property and stability. Revealing the fundamental connections between morphological parameters at different length scales and mechanical parameters 170,171 (elastic modulus, fracture energy, crack-onset strain, cohesion energy, toughness, and so on) warrants in-depth explorations. In future studies, a full set of polymer structure-morphology-property correlations should be further clarified to provide design rules for commercially viable novel All-PSCs.…”

Section: • Determining the Interaction Parameters And Molecular Misci...mentioning

confidence: 99%

Morphology control in high‐efficiency all‐polymer solar cells

Zhou

Xian

2022

InfoMat

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All-polymer solar cells (All-PSCs) have attracted tremendous research interest in the recent decade due to the great potentials in stretchable electronic applications in terms of long-term stability and mechanical stretchability. Driven by the molecular design of novel polymer acceptors and morphology optimization, the power conversion efficiency (PCE) of All-PSCs has developed rapidly and now exceeded 17%. This review outlines the promising strategies for high-performance All-PSCs from the aspect of morphology control with the motivation to rationally guide the optimization. In this review, we briefly discuss the thermodynamic mixing principles of all-polymer blends and the effects of the molecular structure of conjugated polymers on thin-film morphology in All-PSCs. The crucial role of molecular miscibility in influencing morphological features and performance metrics was highlighted. We also expound on the effective methods of controlling film morphology through properly tuning the aggregation behavior of polymers. In particular, insightful studies on the commonly used naphthalene diimide-based acceptor polymers and the newly emerging polymerized nonfullerene small molecule acceptors (ITIC-series, Y6 -series, etc) are discussed in detail. Finally, we present an outlook on the major challenges and the new opportunities of All-PSCs for efficiency breakthroughs targeting 20%.

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Thermoplastic Elastomer Tunes Phase Structure and Promotes Stretchability of High‐Efficiency Organic Solar Cells

Cited by 133 publications

References 77 publications

Insulating Polymers as Additives to Bulk‐Heterojunction Organic Solar Cells: The Effect of Miscibility

Insulating Polymers as Additives to Bulk‐Heterojunction Organic Solar Cells: The Effect of Miscibility

Eco‐friendly solution processing of all‐polymer solar cells: Recent advances and future perspective

Morphology control in high‐efficiency all‐polymer solar cells

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