High‐Efficiency Sequential‐Cast Organic Solar Cells Enabled by Dual Solvent‐Controlled Polymer Aggregation

Li, Xinrui; Cao, Luye; Yu, Xin; Du, Xiaoyang; Lin, Hui; Yang, Gang; Chen, Zhenhua; Zheng, Caijun; Tao, Silu

doi:10.1002/solr.202200076

Cited by 19 publications

(18 citation statements)

References 52 publications

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“…Li et al. [ 372 ] addressed a dual solvent treatment strategy, which aims to add a second solvent (CF or THF) to the D18‐Cl solution with CB as solvent to balance the dissolution and crystallization of the donor, and optimize the morphology of the D18‐Cl layer. Then the subsequent Y6 solution will penetrate into the D18‐Cl layer uniformly, achieving a suitable vertical phase separation.…”

Section: Advanced Device Fabrication Technologiesmentioning

confidence: 99%

“…By delicately tailoring the balance of solubility and evaporation rate of acceptor solvent, CF and XY were selected to fabricate gradient phase separation, which benefits the charge transport and endows high PCE even with thick active layers prepared by blade-coating techniques. Li et al [372] addressed a dual solvent treatment strategy, which aims to add a second solvent (CF or THF) to the D18-Cl solution with CB as solvent to balance the dissolution and crystallization of the donor, and optimize the morphology of the D18-Cl layer. Then the subsequent Y6 solution will penetrate into the D18-Cl layer uniformly, achieving a suitable vertical phase separation.…”

Section: Stable Vertical Morphology Via Sequential Depositionmentioning

confidence: 99%

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Recent Developments of Polymer Solar Cells with Photovoltaic Performance over 17%

Jin

Wang

et al. 2023

Adv Funct Materials

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With the emergence of ADA'DA-type (Y-series) non-fullerene acceptors (NFAs), the power conversion efficiencies (PCEs) of organic photovoltaic devices have been constantly refreshed and gradually reached 20% in recent years (19% for single junction and 20% for tandem device). The acceptors possess specific design concept, which greatly enrich the NFA types and have excellent compatibility with many donor materials. It is gratifying to note that the previously underperforming donor materials combine with these regulated acceptors to shine again. Nowadays, the concept of modular design is widely used in the research of acceptors and donors, injecting new vitality into the field of organic photovoltaics. Furthermore, these acceptors also promote the research of multicomponent devices, tandem devices, bilayer devices, processing solvent engineering, and additive engineering. Herein, the latest progresses of polymer solar cells with efficiency over 17% are briefly reviewed from the aspects of active material design, interface material development, and device technology. At last, the opportunities and challenges of organic photovoltaic commercialization in the future are discussed.

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Section: Advanced Device Fabrication Technologiesmentioning

confidence: 99%

Section: Stable Vertical Morphology Via Sequential Depositionmentioning

confidence: 99%

Recent Developments of Polymer Solar Cells with Photovoltaic Performance over 17%

Jin

Wang

et al. 2023

Adv Funct Materials

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“…Therefore, it gradually evolves to the equilibrium state, causing the suboptimal morphology 19 , 20 . Some valid strategies like using solid additives 21 , 22 , designing oligomer molecular and polymer acceptors 23 , 24 , establishing structure device 25 , as well as introducing a third donor or acceptor component have been extensively explored to significantly suppress the burn-in losses for NFA-based OSCs 26 . However, almost no state-of-the-art OSCs could deliver a satisfied T 80 lifetime under thermal or illumination stress so far.…”

Section: Introductionmentioning

confidence: 99%

Mastering morphology of non-fullerene acceptors towards long-term stable organic solar cells

Zhong

Feng

et al. 2023

Nat Commun

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Despite the rapid progress of organic solar cells based on non-fullerene acceptors, simultaneously achieving high power conversion efficiency and long-term stability for commercialization requires sustainable research effort. Here, we demonstrate stable devices by integrating a wide bandgap electron-donating polymer (namely PTzBI-dF) and two acceptors (namely L8BO and Y6) that feature similar structures yet different thermal and morphological properties. The organic solar cell based on PTzBI-dF:L8BO:Y6 could achieve a promising efficiency of 18.26% in the conventional device structure. In the inverted structure, excellent long-term thermal stability over 1400 h under 85 °C continuous heating is obtained. The improved performance can be ascribed to suppressed charge recombination along with appropriate charge transport. We find that the morphological features in terms of crystalline coherence length of fresh and aged films can be gradually regulated by the weight ratio of L8BO:Y6. Additionally, the occurrence of melting point decrease and reduced enthalpy in PTzBI-dF:L8BO:Y6 films could prohibit the amorphous phase to cluster, and consequently overcome the energetic traps accumulation aroused by thermal stress, which is a critical issue in high efficiency non-fullerene acceptors-based devices. This work provides insight into understanding non-fullerene acceptors-based organic solar cells for improved efficiency and stability.

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“…With the expanding demand for clean energy, organic solar cells (OSCs), as a promising photovoltaic technology for renewable energy, have become one of the research hotspots in recent years thanks to their benefits, such as light weight, solution processability, large area preparation of flexible devices, and roll-to-roll production. − For the problems of efficiency and stability of OSCs, improvements of active layer materials, device structure process, and regulation of interface layer have been proposed for improvement. − At present, the efficiency of OSCs has reached 20% and is gradually developing toward commercialization requirements. , However, because organic semiconductor materials usually present low exciton diffusion length, thus the widely studied organic solar cell structures are transformed from planar heterojunction (PHJ) to bulk heterojunction (BHJ) . In the BHJ structure, the donor and acceptor are mixed to form a bicontinuous interpenetrating network with a large interfacial area for efficient exciton dissociation .…”

Section: Introductionmentioning

confidence: 99%

Efficient and Stable Ternary Organic Solar Cells Using Liquid Crystal Small Molecules with Multiple Synergies

Wen

Lin

et al. 2022

ACS Appl. Energy Mater.

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A liquid crystal small molecule donor BTR-Cl, which has strong self-assembly and crystallinity, is used as the third component to construct nonfullerenes ternary solar cells together with a broad-band donor polymer D18-Cl and a low-band acceptor N3. The introduction of BTR-Cl enhances the morphology, exciton dissociation, and charge mobility of the ternary blends, improves the short-circuit current density and fill factor, and results in an efficiency of up to 17.92%. Further results show that BTR-Cl acts as an energy level mediator, fluorescence resonance energy transfer and charge transfer intermediary, and morphology modifier in ternary blends. They work synergistically in ternary blends to optimize the electrical and morphological properties, resulting in enhanced photovoltaic performance and improved stability and detection performance. It brings vitality to the field of organic solar cells (OSCs) and organic photodetectors (OPDs) research.

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High‐Efficiency Sequential‐Cast Organic Solar Cells Enabled by Dual Solvent‐Controlled Polymer Aggregation

Cited by 19 publications

References 52 publications

Recent Developments of Polymer Solar Cells with Photovoltaic Performance over 17%

Recent Developments of Polymer Solar Cells with Photovoltaic Performance over 17%

Mastering morphology of non-fullerene acceptors towards long-term stable organic solar cells

Efficient and Stable Ternary Organic Solar Cells Using Liquid Crystal Small Molecules with Multiple Synergies

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