非富勒烯电子受体多尺度分子聚集体

有机太阳能电池的光活性层由p型电子供体和n型电子受体构成.这些有机半导体分子的共轭结构和杂元素使其分子间存在强非共价键作用,易于自组装形成分子聚集体,展现出与单个分子截然不同的光电性能,更决定了太阳能电池光吸收、激子解离和电荷传输等光电转换过程.本文介绍了n型非富勒烯电子受体材料在分子及微纳尺度下的多级聚集体形态,包括强结晶性非富勒烯受体的堆叠、成核、结晶机制与抑制手段,以及弱有序非富勒烯受体无规聚集及有序性提升策略.最后,重点讨论了非富勒烯电子受体纤维化的研究进展及关键技术,并对未来高性能非富勒烯电子受体的结构设计和聚集调控进行了总结和展望.     

基于芳环取代酰亚胺端基的非富勒烯受体材料的合成与光伏性能

端基结构对于有机太阳能电池(OSCs)中非富勒烯受体(NFAs)的光电性能具有重要影响.本文设计合成了3种新型芳环取代的酰亚胺结构的端基(IIC-Ph, IIC-PhBr和IIC-Ph2F),并将其用于制备受体-给体(受体)给体-受体(A-DA′D-A)型NFAs(BTP-IIC-Ph, BTP-IIC-PhBr和BTP-IIC-Ph2F).紫外-可见-近红外吸收光谱对比和理论模拟结果表明,相比于IIC-Ph端基, IIC-PhBr和IIC-Ph2F端基具有更强的吸电子能力,增强了NFAs的分子内电荷转移效应(ICT),促使了吸收红移.端基苯环上强吸电子的溴原子和氟原子的引入,降低了A-DA′D-A型受体的前线轨道能级.基于BTP-IIC-Ph, BTP-IIC-PhBr和BTP-IIC-Ph2F的二元电池分别获得了13.54%, 11.84%和11.58%的能量转换效率(PCEs).相比于BTP-IIC-PhBr和BTP-IIC-Ph2F,基于BTP-IIC-Ph的电池表现出更好的光伏性能,这主要归因于其较高的最低未占有轨道能级(LUMO)所导致的较高开路电压(VOC),以及更好的激...     

基于非富勒烯电子受体的半透明有机太阳能电池

半透明有机太阳能电池以其独特的光电特性在建筑集成光伏上具有广阔的应用前景。非富勒烯小分子受体近几年发展十分迅速。其中,基于非富勒烯小分子受体的半透明有机太阳能电池具有较高的光电转换效率和平均可见光透过率,因而得到了广泛关注。本文总结了近几年来非富勒烯受体型半透明有机太阳能电池的最新研究进展,探究活性层材料设计及器件构型优化对半透明有机太阳能电池的影响,希望为半透明有机太阳能电池在今后研究中新材料体系的优选提供一定的参考。     

含萘并二噻吩小分子受体材料的带隙调控及其在非富勒烯太阳能电池中的应用

By using photovoltaic technology, ambient solar light can be directly converted to electricity. The photovoltaic technology has been regarded as one of the most important and promising strategies to resolve the worldwide energy and pollution problems. As one type of photovoltaic technology, polymer solar cells have attracted increasing interest due to their advantages of solution processing capability, low-cost, feasibility to be fabricated on flexible substrates etc. Not until a few years ago, the fullerene derivatives had been dominated the organic photovoltaic field as the most promising acceptor materials for polymer solar cells. However, fullerene-based polymer solar cells have a power conversion efficiency bottleneck due to the relatively fixed energy levels as well as the fixed bandgaps of fullerene derivatives. Therefore, researchers started to develop nonfullerene acceptors which can be used as alternatives to replace the traditional fullerene derivatives. Compared to the fullerene derivatives, nonfullerene acceptors offer several advantages such as stronger light absorption, tunable bandgaps and frontier molecular orbital energy levels. For nonfullerene acceptors, a ladder-type fused ring is usually used as the central core which is an essential building block to tailor the bandgaps and energy levels. Although many fused ring systems have been explored for efficient nonfullerene acceptors, ladder-type angular-shape dithienonaphthalene is seldom reported as the donor unit for nonfullerene acceptors. Furthermore, the impact of thiophene bridge on the optical and photovoltaic properties of the dithienonaphthalene-based nonfullerene acceptors has never been reported. In this context, we report on the design and synthesis of a dithienonaphthalene-based small-molecule acceptor which contains thiophene bridges in between the acceptor terminals and the fused-ring donor core. Compared to the dithienonaphthalene-based small-molecule without the thiophene bridges, the resulting acceptor (DTNIT) exhibits a reduced bandgap of 1.52 eV which makes it more suitable to be blended with the benchmark large bandgap copolymer, poly[(2, 6-(4, 8-bis(5-(2-ethylhexyl)thiophen-2-yl)-benzo[1, 2-b: 4, 5-b']dithiophene))-alt-(5, 5-(1', 3'-di-2-thienyl-5', 7'-bis(2-ethylhexyl)benzo[1', 2'-c:4', 5'-c']dithiophene-4, 8-dione)] (PBDB-T). The reduced band-gap of the resulting nonfullerene acceptor can be attributed to its extended π-conjugation in comparison with the dithienonaphthalene-based acceptor without the thiophene bridges. Inverted polymer solar cells with a device configuration of indium tin oxide/ZnO/PBDB-T:DTNIT/MoO₃/Ag were fabricated and characterized. Polymer solar cells based on PBDB-T:DTNIT showed an open circuit voltage of 0.91 V, an enhanced short circuit current of 14.42 mA∙cm⁻², and a moderate PCE of 7.05% which is comparable to the PCE of 7.12% for the inverted device based on PBDB-T:PC₇₁BM. Our results not only provide a method to synthesize efficient nonfullerene acceptors with reduced bandgaps, but also offer a bandgap modulation strategy for nonfullerene acceptors.     

基于非富勒烯小分子受体Y6的有机太阳能电池

随着给/受体材料的不断发展,有机太阳能电池的器件效率不断取得进展.特别是非富勒受体分子Y6的出现,使单结有机太阳能电池的效率突破了15％.Y6已经应用到了有机太阳能电池各个方面并且极大提升了其性能.本综述主要总结了Y6在二元、三元和四元、逐层印刷、柔性、叠层和半透明等有机太阳能电池方面的研究情况,以及基于Y6三线态的有...     

骨架非稠合的电子受体在聚合物太阳能电池中的应用

Non-fullerene electron acceptors have attracted enormous attention of the research community owing to their advantages of optoelectronic and chemical tunabilities for promoting high-performance polymer solar cells (PSCs). Among them, fused-ring electron acceptors (FREAs) are the most popular ones with the good structural planarity and rigidity, which successfully boost the power conversion efficiencies (PCEs) of PSCs to over 14%. In considering the cost-control of future scale-up applications, it is also worthwhile to explore novel structures that are easy to synthesize and still maintain the advantages of FREAs. In this work, we design and synthesize a new electron acceptor with an unfused backbone, 5, 5'-((2, 5-bis((2-hexyldecyl)oxy)-1, 4-phenylene)bis(thiophene-2-yl))bis(methanylylidene)) bis(3-oxo-2, 3-dihydro-1H-indene-2, 1-diylidene))dimal-ononitrile (ICTP), which contains two thiophenes and one alkoxy benzene as the core and 2-(3-oxo-2, 3-dihydroinden-1-ylidene) malononitrile (IC) as the terminal groups. The synthetic route to ICTP involves only three steps, with high yields. Density functional theory calculations indicate that the non-covalent interactions, O…H and O…S, help reinforce the space conformation between the central core and the terminals. ICTP shows broad and strong absorption in the long-wavelength range between 500 and 760 nm. The highest occupied molecular orbital and lowest unoccupied molecular orbital levels of ICTP were measured to be -5.56 and -3.84 eV by cyclic voltammetry. The suitable absorption and energy levels make ICTP a good acceptor candidate for medium bandgap polymer donors. The best devices based on PBDB-T:ICTP showed a PCE of 4.43%, with an open circuit voltage (V_OC) of 0.97 V, a short circuit current density (J_SC) of 8.29 mA∙cm^-2, and a fill factor (FF) of 0.55, after adding 1% 1, 8-diiodooctane (DIO) as the solvent additive. Atomic force microscopy revealed that DIO could ameliorate the strong aggregation in the blended film and lead to a smoother film surface. The hole and electron mobilities of the optimized device were measured to be 9.64 and 2.03 × 10^-5 cm²∙V^-1∙s^-1, respectively, by the space-charge-limited current method. The relatively low mobilities might be responsible for the moderate PCE. Further studies can be performed to enlarge the conjugation length by including more aromatic rings. This study provides a simple strategy to design non-fullerene acceptors and a valuable reference for the future development of PSCs.     

协同富勒烯和非富勒烯受体提高卟啉全小分子三元有机太阳能电池的性能

将非富勒烯受体2,2′-{(2Z,2′Z)-[4,4,9,9-四(对己基苯)-4,9-二氢-S-引达省并二噻吩-2,7-二基]双(甲基亚基)}-双-(3-氧代-2,3-二氢-1H-茚-2,1-二亚甲基)二丙二腈(IDIC)作为第三组分引入小分子给体卟啉二聚体ZnP2-DPP和富勒烯(6,6)-苯基-C61-丁酸甲酯(PC₆₁BM)受体体系,构建了光电转换效率达12.18%的全小分子有机太阳能电池,高于ZnP2-DPP∶PC₆₁BM的9.47%和ZnP2-DPP∶IDIC的8.82%的光电转换效率.IDIC的引入扩大了光谱的吸收范围,并且促进了给受体之间的电荷转移,使得三元共混物中可以产生更高的光电流.另外,IDIC的加入优化了共混膜的形貌,分子取向也得到了明显的调整,形成了face-on和edge-on的混合取向,从而使活性层中形成了更有利的三维电荷传输通道,促进了短路电流密度和填充因子的提高.这种策略发挥了富勒烯和非富勒烯受体的优势,从而提高了有机太阳能电池的4个参数.     

含有萘酰亚胺的菁染料太阳能电池敏化剂的合成

通过Click反应把萘酰亚胺化合物连接到含有醛基的吲哚上,再通过醛基和吲哚碘盐的Knoevenagel缩合反应合成出带有萘酰亚胺部分的菁染料,用NMR、MS、元素分析、UV-Vis等方法对其结构和性能进行了表征和测试。     

卟啉类光敏剂在染料敏化太阳能电池中的应用

染料是染料敏化太阳能电池的核心之一,它的性质直接影响着电池的光电转换效率.多吡啶钌类配合物是目前最有效的染料,但存在合成困难、需要贵金属钌且对环境有一定的污染等缺点,因此近年来纯有机及含廉价金属染料的研究逐渐受到重视.卟啉类染料具有易合成、易修饰及在可见光区有强吸收等特性,这些特性使它在非钌染料的研究中受到青睐.本文从...     

基于非富勒烯受体的溶液加工型全小分子太阳能电池研究进展

有机太阳能电池(OPV),具有质量轻、可成本低制备等优势,是一种具有实际应用潜力的光伏技术。有机太阳能电池活性层可以由共轭聚合物或溶液可加工的小分子材料(给体与受体)共混组成。由于小分子材料具有明确的分子结构,纯度可控及无批次差别影响的特点;并结合近年来非富勒烯小分子受体的快速发展,使得非富勒烯全小分子(NF-SM-OPV)电池研究受到广泛关注。由于大部分A-D-A型非富勒烯受体分子具有各向异性的特点,这使激子解离和电荷传输,很大程度上受分子间堆积方式的影响,导致非富勒烯全小分子电池活性层形貌调控更加复杂。虽然非富勒烯小分子太阳能电池具有非富勒烯受体材料和小分子材料的双重优势,但高效率非富勒烯小分子太阳能电池的制备,仍具有很大挑战。因此,本文总结近年来高性能非富勒烯小分子太阳能电池的相关进展。着重介绍针对非富勒烯受体的给体小分子材料设计工作,并在此基础上近一步讨论非富勒烯小分子太阳能电池面临的挑战与展望。     

Effect of the Terminal Acceptor Unit on the Performance of Non-Fullerene Indacenodithiophene Acceptors in Organic Solar Cells

Four acceptor–donor–acceptor (A–D–A)-type molecules bearing indacenodithiophene as donating central core and various end-capping acceptor units have been designed and synthesised as n-type materials suitable for organic solar cells (OSCs). The studied optical and electrochemical properties supported by theoretical calculations revealed that the nature and the strength of the terminal groups exert a decisive influence on the polymer bulk-heterojunction OSC performance.     

带有噻吩侧基的有机硼小分子电子受体光伏材料

有机小分子电子受体材料的侧基能够影响异质结有机太阳能电池的给体/受体匹配和器件性能。我们设计并合成了一个硼原子带有噻吩侧基的有机硼小分子(MBN-Th)。该分子的LUMO离域在整个骨架上,HOMO定域在中心核上,其独特的电子结构使该分子具有两个强的吸收峰(波长分别为490和726nm),因此分子具有宽的吸收光谱和强的太阳光吸收能力。与苯基侧基相比,噻吩侧基使分子的HOMO能级下移0.1 eV,LUMO能级保持不变,进而引起分子带隙减小和吸收光谱蓝移20nm。基于该有机硼小分子受体材料的异质结有机太阳能电池,实现了4.21%的能量转化效率和300–850nm的宽响应光谱。实验结果表明,硼原子上的噻吩侧基是调控有机硼小分子光电性质的有效方法,可以用于有机硼小分子受体材料的设计。     

Multicomponent Solar Cells with High Fill Factors and Efficiencies Based on Non-Fullerene Acceptor Isomers

Multicomponent organic solar cells (OSCs), such as the ternary and quaternary OSCs, not only inherit the simplicity of binary OSCs but further promote light harvesting and power conversion efficiency (PCE). Here, we propose a new type of multicomponent solar cells with non-fullerene acceptor isomers. Specifically, we fabricate OSCs with the polymer donor J71 and a mixture of isomers, ITCF, as the acceptors. In comparison, the ternary OSC devices with J71 and two structurally similar (not isomeric) NFAs (IT-DM and IT-4F) are made as control. The morphology experiments reveal that the isomers-containing blend film demonstrates increased crystallinity, more ideal domain size, and a more favorable packing orientation compared with the IT-DM/IT-4F ternary blend. The favorable orientation is correlated with the balanced charge transport, increased exciton dissociation and decreased bimolecular recombination in the ITCF-isomer-based blend film, which contributes to the high fill factor (FF), and thus the high PCE. Additionally, to evaluate the generality of this method, we examine other acceptor isomers including IT-M, IXIC-2Cl and SY1, which show same trend as the ITCF isomers. These results demonstrate that using isomeric blends as the acceptor can be a promising approach to promote the performance of multicomponent non-fullerene OSCs.     

基于一种新型聚噻吩衍生物为给体的非富勒烯聚合物太阳能电池

With the development of non-fullerene small-molecule acceptors, non-fullerene polymer solar cells (PSCs) have garnered increased attention due to their high performance. While photons are absorbed and converted to free charge carriers in the active layer, the donor and acceptor materials both play a critical role in determining the performance of PSCs. Among the various conjugated-polymer donor materials, polythiophene (PT) derivatives such as poly(3-hexylthiophene), have attracted considerable interest due to their high hole mobility and simple synthesis. However, there are limited studies on the applications of PT derivatives in non-fullerene PSCs. Fabrication of highly efficient non-fullerene PSCs utilizing PT derivatives as the donor is a challenging topic. In this study, a new PT derivative, poly[5, 5′-4, 4′-bis(2-butyloctylsulphanyl)-2, 2′-bithiophene-alt-5, 5′-4, 4′-difluoro-2, 2′-bithiophene] (PBSBT-2F), with alkylthio groups and fluorination was synthesized for use as the donor in non-fullerene PSC applications. The absorption spectra, electrochemical properties, molecular packing, and photovoltaic properties of PBSBT-2F were investigated and compared with those of poly(3-hexylthiophene) (P3HT). The polymer exhibited a wide bandgap of 1.82 eV, a deep highest occupied molecular orbital (HOMO) of -5.02 eV, and an ordered molecular packing structure. Following this observation, PSCs based on a blend of PBSBT-2F as the donor and 3, 9-bis(2-methylene-(3-(1, 1-dicyanomethylene)-indanone)-5, 5, 11, 11-tetrakis(4-hexylphenyl)-dithieno-[2, 3-d:2′, 3′-d′]-s-indaceno[1, 2-b:5, 6-b′]dithiophene (ITIC) as the acceptor were fabricated. The absorption spectra were collected and the energy levels were found to be well matched. These devices exhibited a power conversion efficiency (PCE) of 6.7% with an open-circuit voltage (V_OC) of 0.75 V, a short-circuit current density (J_SC) of 13.5 mA·cm^-2, and a fill factor (FF) of 66.6%. These properties were superior to those of P3HT (1.2%) under the optimal conditions. This result indicates that PBSBT-2F is a promising donor material for non-fullerene PSCs.     

A-D-A型小分子电子给体光伏材料的端基修饰及其光伏性能

有机太阳能电池(OSCs)活性层中的给体材料主要包括共轭聚合物与有机小分子,由于有机小分子给体具有结构确定、易于提纯、重复性高等独特的优势,近年来受到研究工作者的广泛关注。本工作中,我们采取具有良好共平面性的三联苯并二噻吩(TriBDT-T)为推电子(D)中心共轭单元,分别以罗丹宁(RN)、氰基罗丹宁(RCN)和1,3-茚二酮(IDO)为拉电子(A)共轭端基,设计并合成了三种具有A-D-A型结构的小分子给体材料TriBDT-T-RN、TriBDT-T-RCN和TriBDT-T-IDO。我们对比研究了三种端基对其热分解温度、吸收光谱和分子能级等基本性能的影响,并分别将三种小分子给体与非富勒烯型受体材料IT-4F共混制备器件,详细研究了活性层形貌与光伏性能之间的关系。结果表明,不同的A型端基对小分子给体材料的光学性能、电化学性能、光伏器件中活性层的微观形貌以及能量转换效率(PCE)产生显著影响。基于TriBDTT-RN:IT-4F、TriBDT-T-RCN:IT-4F和TriBDT-T-IDO:IT-4F的光伏器件的能量转换效率分别为9.25%、6.31%和6.18%。