Highly Efficient All‐Polymer Solar Cells Enabled by Random Ternary Copolymer Acceptors with High Tolerance on Molar Ratios

Wu, Yao; Wu, Qiang; Wang, Wei; Sun, Rui; Min, Jie

doi:10.1002/solr.202000409

Cited by 17 publications

(19 citation statements)

References 54 publications

(88 reference statements)

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“…The all‐PSC device based on the PBDB‐T:PYTS‐0.0 blend showed a PCE of 13.01% with an open‐circuit voltage ( V oc ) of 0.92 V and a J sc of 22.38 mA cm –2 , which is comparable to the reported values. [ 55 ] Notably, the all‐PSCs with PBDB‐T:PYTS‐0.3 blend showed a remarkably high PCE of 14.68% with a high J sc of 22.91 mA cm –2 , and FF of 0.70. However, the blends with high content of the FCBS units exhibited significantly low performances (with a PCE of 1.71% for the PBDB‐T:PYTS‐1.0‐based device).…”

Section: Resultsmentioning

confidence: 99%

Polymer Acceptors with Flexible Spacers Afford Efficient and Mechanically Robust All‐Polymer Solar Cells

et al. 2021

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High efficiency and mechanical robustness are both crucial for the practical applications of all‐polymer solar cells (all‐PSCs) in stretchable and wearable electronics. In this regard, a series of new polymer acceptors (PAs) is reported by incorporating a flexible conjugation‐break spacer (FCBS) to achieve highly efficient and mechanically robust all‐PSCs. Incorporation of FCBS affords the effective modulation of the crystallinity and pre‐aggregation of the PAs, and achieves the optimal blend morphology with polymer donor (PD), increasing both the photovoltaic and mechanical properties of all‐PSCs. In particular, an all‐PSC based on PYTS‐0.3 PA incorporated with 30% FCBS and PBDB‐T PD demonstrates a high power conversion efficiency (PCE) of 14.68% and excellent mechanical stretchability with a crack onset strain (COS) of 21.64% and toughness of 3.86 MJ m‐3, which is significantly superior to those of devices with the PA without the FCBS (PYTS‐0.0, PCE = 13.01%, and toughness = 2.70 MJ m‐3). To date, this COS is the highest value reported for PSCs with PCEs of over 8% without any insulating additives. These results reveal that the introduction of FCBS into the conjugated backbone is a highly feasible strategy to simultaneously improve the PCE and stretchability of PSCs.

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Section: Resultsmentioning

confidence: 99%

Polymer Acceptors with Flexible Spacers Afford Efficient and Mechanically Robust All‐Polymer Solar Cells

et al. 2021

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“…To date, although enormous research efforts have been dedicated to developing near-infrared (NIR) P A s, 16,17,23 very few can afford impressive PCEs of over 14% in all-PSCs when blended with the P D PBDB-T derivatives (Table S1). 18,22,[24][25][26][27] Of note is that all these structures are based exclusively on one kind of electron-deficient unit (a Y5 derivative) (Figure S1). In addition, these P A s, formed by polymerization of a non-fullerene acceptor, generally retain the merits of SM-NFAs, such as strong absorbing properties and/or capabilities in the NIR region, tunable energy levels, and good charge transport properties.…”

Section: Context and Scalementioning

confidence: 99%

Achieving over 17% efficiency of ternary all-polymer solar cells with two well-compatible polymer acceptors

Sun

Wang

Han

et al. 2021

Joule

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295

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“…[ 25,26 ] Thus, reasonable use of different morphology control strategies, such as modification of molecular structures, [ 5,9,21,27 ] selection of solvent and additive, [ 6,20,28 ] thermal annealing, [ 6,22 ] and so on, to modify domain size and phase purity in all‐PSCs is critical. For instance, various random ternary copolymerization strategies were purposed to design P A derivatives, including naphthalene diimide (NDI)‐based N2200 derivatives (PNDI‐CBS 0.5 and BSS10), [ 21,29 ] and Y6‐like PSMAs (PTPBT‐ET 0.3 and PYE 0.2 ), [ 14,30 ] etc., for improving effectively phase‐separated BHJ morphologies. Nevertheless, the consumption and risk on trial and error experiments in terms of material design are huge.…”

Section: Introductionmentioning

confidence: 99%

High‐Performance All‐Polymer Solar Cells with a Pseudo‐Bilayer Configuration Enabled by a Stepwise Optimization Strategy

Wang

et al. 2021

Adv Funct Materials

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112

105

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In this work, an efficiency of 15.17% in the PBDB‐T/PYT all‐PSCs fabricated by a layer‐by‐layer (LbL) deposition technique is achieved by synergistically controlling additive dosages, which is not only higher than that (14.06%) of the corresponding bulk heterojunction (BHJ) device, but also the top efficient for all‐PSCs. Through the studies of physical dynamics and morphological characteristics, it is found that the LbL film can effectively improve optical and electronic properties, ensure exciton separation, charge generation and extraction, reduce trap‐assisted recombination, and facilitate hole transfer in LbL blends, thus achieving higher performance compared to its BHJ counterpart. Notably, the synergistic regulation of additive dosages in donor and acceptor solutions is also confirmed in the other three photovoltaic systems. Of particular note is that over 15% device performance is also achieved in the PBDB‐T/PYT LbL all‐PSCs fabricated via a blade‐coating technique, further demonstrating the great significance of this synergistic additive‐doping strategy for the printing fabrication of organic photovoltaics.

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Highly Efficient All‐Polymer Solar Cells Enabled by Random Ternary Copolymer Acceptors with High Tolerance on Molar Ratios

Cited by 17 publications

References 54 publications

Polymer Acceptors with Flexible Spacers Afford Efficient and Mechanically Robust All‐Polymer Solar Cells

Polymer Acceptors with Flexible Spacers Afford Efficient and Mechanically Robust All‐Polymer Solar Cells

Achieving over 17% efficiency of ternary all-polymer solar cells with two well-compatible polymer acceptors

High‐Performance All‐Polymer Solar Cells with a Pseudo‐Bilayer Configuration Enabled by a Stepwise Optimization Strategy

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