A Highly Planar Nonfullerene Acceptor with Multiple Noncovalent Conformational Locks for Efficient Organic Solar Cells

Yang, Lei; Gu, Wenxing; Yang, Yufei; Lei, Hong; Zhang, Xutao; Xiao, Yu; Wu, Xiaoxi; Peng, Aidong; Huang, Hui

doi:10.1002/smtd.201700330

Cited by 39 publications

(19 citation statements)

References 51 publications

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“…In this work, we choose benzobis(thiazole) (BBTz) and cyclopentadithiophene (CPDT) as molecular core and donor units, respectively, to check the above molecular design strategy. The BBTz unit was chosen for the design of nonfullerene acceptors, despite rarely utilized in photovoltaic materials, due to the following considerations: 1) S···N noncovalent interaction can be formed between the nitrogen atom of the BBTz unit and the sulfur atom of the CPDT unit to lock the molecular geometry, 2) the quinoid‐resonance effect of the BBTz unit can be utilized to narrow the bandgap of the nonfullerene acceptors, 3) the electron‐withdrawing property of BBTz unit can help lower the HOMO level. The D‐C‐D molecular structure is flanked by two different electron‐withdrawing terminals, (2‐(5,6‐difluoro‐3‐oxo‐2,3‐dihydro‐1 H ‐inden‐1‐ylidene)malononitrile and 2‐(6‐oxo‐5,6‐dihydro‐4 H ‐cyclopenta[ c ]thiophen‐4‐ylidene)malononitrile), to check the effect of terminals on the device performance, thus resulting in two novel nonfullerene acceptors (X‐PCIC and X1‐PCIC) with similar properties in the absorption range and energy levels, but a significant difference in terminal packing strength.…”

Section: Introductionmentioning

confidence: 99%

Near‐Infrared Nonfullerene Acceptors Based on Benzobis(thiazole) Unit for Efficient Organic Solar Cells with Low Energy Loss

Zhan

Lau

et al. 2019

Small Methods

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The simultaneous achievement of a low energy loss and high external quantum efficiency (EQE) response is the prerequisite for high power conversion efficiencies of organic solar cells (OSCs). Herein, this issue is examined through the design of two novel near‐infrared (NIR) nonfullerene acceptors (X‐PCIC and X1‐PCIC) with an absorption extending to 900 nm, which is realized by using benzobis(thiazole) unit as the core. This study reveals that benzobis(thiazole) unit with the quinoid‐resonance effect and electron‐withdrawing property is a good building block in extending absorption and maintaining suitable energy levels. Single crystal cultivation proves the function of S···N noncovalent interaction in locking molecular geometry. Besides, through adopting two different terminals (fluorinated terminal for X‐PCIC and thiophene‐fused terminal for X1‐PCIC), it is found that an increase in the J‐aggregation strength has a significant positive effect on the EQE response of the devices through the formation of more suitable domain sizes and crystallinity in the films, while the energy loss remains low (≈0.53 eV) and unaffected. Thus, a high efficiency of 11.50% is presented for OSC based on the X‐PCIC with stronger J‐aggregation strength, better than that (10.17%) based on the X1‐PCIC with weaker J‐aggregation strength. This work clearly demonstrates the application of benzobis(thiazole) unit in efficient small molecule acceptors and the importance of J‐aggregation modulation for the simultaneous achievement of low energy loss and high EQE response.

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Section: Introductionmentioning

confidence: 99%

Near‐Infrared Nonfullerene Acceptors Based on Benzobis(thiazole) Unit for Efficient Organic Solar Cells with Low Energy Loss

Zhan

Lau

et al. 2019

Small Methods

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“…To the best of our knowledge, it is worth pointing that the PCE of 12.5% is the highest value for unfused A 1 –D–A 2 –D–A 1 ‐SMAs with the electron‐deficient unit as central A 2 unit in binary PSCs, and is also the highest PCE for unfused ring NF‐SMA‐based PSCs with a V oc > 0.9 V (see Scheme 1 and Table S1 in the Supporting Information). [ 53,57–59,62,63,69–73 ] These results reveal that the central electron‐deficient unit have significantly impact on the device performance and BT2FIDT‐4Cl with difluorobenzothiadiazole is a good choice to achieve highly efficient A 1 –D–A 2 –D–A 1 unfused ring NF‐SMAs with high V oc .…”

Section: Resultsmentioning

confidence: 95%

“…For the high performance (PCE > 12%) of unfused ring SMA‐based device, most of the corresponding V oc are distributed in the range of 0.85–0.89 V. [ 54,64,66,68,69 ] Once the V oc is further increased to over 0.90 V, the PCEs will drop sharply. [ 57,58,62,63,69–73 ] Thus, it is necessary to find more effective strategies to synthesize novel unfused ring NF‐SMAs to achieve both high V oc and high FF, simultaneously, thus improving the PCE.…”

Section: Introductionmentioning

confidence: 99%

Electron‐Deficient and Quinoid Central Unit Engineering for Unfused Ring‐Based A₁–D–A₂–D–A₁‐Type Acceptor Enables High Performance Nonfullerene Polymer Solar Cells with High V_oc and PCE Simultaneously

Zhang

Song

Liu

et al. 2020

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Here, a pair of A1–D–A2–D–A1 unfused ring core‐based nonfullerene small molecule acceptors (NF‐SMAs), BO2FIDT‐4Cl and BT2FIDT‐4Cl is synthesized, which possess the same terminals (A1) and indacenodithiophene unit (D), coupling with different fluorinated electron‐deficient central unit (difluorobenzoxadiazole or difluorobenzothiadiazole) (A2). BT2FIDT‐4Cl exhibits a slightly smaller optical bandgap of 1.56 eV, upshifted highest occupied molecular orbital energy levels, much higher electron mobility, and slightly enhanced molecular packing order in neat thin films than that of BO2FIDT‐4Cl. The polymer solar cells (PSCs) based on BT2FIDT‐4Cl:PM7 yield the best power conversion efficiency (PCE) of 12.5% with a Voc of 0.97 V, which is higher than that of BO2FIDT‐4Cl‐based devices (PCE of 10.4%). The results demonstrate that the subtle modification of A2 unit would result in lower trap‐assisted recombination, more favorable morphology features, and more balanced electron and hole mobility in the PM7:BT2FIDT‐4Cl blend films. It is worth mentioning that the PCE of 12.5% is the highest value in nonfused ring NF‐SMA‐based binary PSCs with high Voc over 0.90 V. These results suggest that appropriate modulation of the quinoid electron‐deficient central unit is an effective approach to construct highly efficient unfused ring NF‐SMAs to boost PCE and Voc simultaneously.

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“…The maximum absorption peaks of PBDT‐F‐2TC and PBDT‐SF‐2TC in solutions are equal to those in films, locating at 540 and 542 nm, respectively. In addition, a weak shoulder peak is observed in both PBDT‐F‐2TC and PBDT‐SF‐2TC thin film, indicating the existence of weak intermolecular interaction in the copolymers . The absorption edge (λ onset ) of the PBDT‐F‐2TC and PBDT‐SF‐2TC are located at 629 and 626 nm, corresponding to an optical bandgap ( E g opt ) of 1.97 and 1.98 eV, respectively.…”

Section: Molecular Weights and Optical And Electrochemical Propertiesmentioning

confidence: 97%

Asymmetric Wide‐Bandgap Polymers Simultaneously Improve the Open‐Circuit Voltage and Short‐Circuit Current for Organic Photovoltaics

Huang

Chen

et al. 2019

Macromol. Rapid Commun.

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A trade‐off between open‐circuit voltage (V OC) and high short‐circuit (J SC) becomes one of the most vital problems limiting further improvement in polymer solar cells' (PSCs) efficiency. In this work, two asymmetric polymer donors PBDT‐F‐2TC and PBDT‐SF‐2TC are designed and synthesized. When blended with a state‐of‐the‐art acceptor IT‐4F with low lowest‐unoccupied molecular orbital level, simultaneously high V OC (up to 0.94 V) and J SC (up to 20.73 mA cm−2) are obtained for both copolymers. Note that the V OC value of 0.94 V is the highest value of PSCs based on IT‐4F reported so far. The simultaneously improved V OC and J SC in resulting devices are discovered from the deep highest‐occupied molecular orbital levels (−5.5 to −5.7 eV) and the hyperchromic effect of the polymers, the small driving force, and the small energy loss during the charge transfer, due to the synergistic effect of asymmetric carboxylate unit and fluorine/sulfur atoms. More importantly, thanks to the asymmetric 2TC, both PBDT‐F‐2TC‐ and PBDT‐SF‐2TC‐based PSCs can be successfully processed by non‐halogenated solvent 1,2,4‐trimethylbenzene (TMB) to yield device efficiencies of 10.29% and 10.39%, respectively, which are the maximum values for non‐fullerene PSCs fabricated using the eco‐friendly solvent TMB.

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A Highly Planar Nonfullerene Acceptor with Multiple Noncovalent Conformational Locks for Efficient Organic Solar Cells

Cited by 39 publications

References 51 publications

Near‐Infrared Nonfullerene Acceptors Based on Benzobis(thiazole) Unit for Efficient Organic Solar Cells with Low Energy Loss

Near‐Infrared Nonfullerene Acceptors Based on Benzobis(thiazole) Unit for Efficient Organic Solar Cells with Low Energy Loss

Electron‐Deficient and Quinoid Central Unit Engineering for Unfused Ring‐Based A₁–D–A₂–D–A₁‐Type Acceptor Enables High Performance Nonfullerene Polymer Solar Cells with High V_oc and PCE Simultaneously

Asymmetric Wide‐Bandgap Polymers Simultaneously Improve the Open‐Circuit Voltage and Short‐Circuit Current for Organic Photovoltaics

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A Highly Planar Nonfullerene Acceptor with Multiple Noncovalent Conformational Locks for Efficient Organic Solar Cells

Cited by 39 publications

References 51 publications

Near‐Infrared Nonfullerene Acceptors Based on Benzobis(thiazole) Unit for Efficient Organic Solar Cells with Low Energy Loss

Near‐Infrared Nonfullerene Acceptors Based on Benzobis(thiazole) Unit for Efficient Organic Solar Cells with Low Energy Loss

Electron‐Deficient and Quinoid Central Unit Engineering for Unfused Ring‐Based A1–D–A2–D–A1‐Type Acceptor Enables High Performance Nonfullerene Polymer Solar Cells with High Voc and PCE Simultaneously

Asymmetric Wide‐Bandgap Polymers Simultaneously Improve the Open‐Circuit Voltage and Short‐Circuit Current for Organic Photovoltaics

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Electron‐Deficient and Quinoid Central Unit Engineering for Unfused Ring‐Based A₁–D–A₂–D–A₁‐Type Acceptor Enables High Performance Nonfullerene Polymer Solar Cells with High V_oc and PCE Simultaneously