无机铅卤钙钛矿纳米晶的合成、性能及应用

无机铅卤钙钛矿CsPbX₃(X=Cl,Br,I)纳米晶因具有较高荧光量子效率(~90%)、发光波长覆盖整个可见光谱(400~700 nm)、半高宽相对较窄(12~42 nm)等诸多优点而备受关注,这些性能使之成为当前最具有潜在应用价值的发光材料之一。 因此,近年来对该类无机铅卤钙钛矿材料的报道越来越多。 本文主要介绍了无机铅卤钙钛矿发光材料的发展历程、结构、制备方法、生长机理及当前的主要应用领域等,最后概括了无机铅卤钙钛矿发光材料在当前研究背景下所面临的问题并展望了下一阶段的发展方向,为进一步提高其光学性能及开发新型高效的无机铅卤钙钛矿发光材料奠定基础。     

金属卤化物钙钛矿纳米晶高效发光二极管的制备与器件性能优化

金属卤化物钙钛矿作为一类新型的离子型直接带隙半导体材料在电致发光二极管(LED)中有着重要应用前景. 但实现其应用的前提在于金属卤化物钙钛矿材料需要保持高的发光效率和好的稳定性. 为了提高金属卤化物钙钛矿作为LED发光层的激子结合效率, 从而提升其发光效率, 设计和合成金属卤化物钙钛矿纳米晶材料是一个有效途径. 目前, 基于纳米晶材料设计的金属卤化物钙钛矿LED在绿光和红光(包括近红外光)范围已经展现了高的发光亮度和外量子效率(EQE), 其中最高EQE已经超过了20%, 但其稳定性仍无法满足器件应用的要求. 此外, 更值得关注且更重要的是, 蓝光钙钛矿LED的发光亮度和EQE目前仍然不高. 如何制备高效、 稳定的金属卤化物钙钛矿纳米晶LED, 特别是蓝光LED, 是一个具有重大应用前景且具有挑战性的课题. 本文重点介绍了金属卤化物钙钛矿纳米发光层的结构设计和合成方法及金属卤化物钙钛矿LED的研究进展, 分析了金属卤化物钙钛矿LED不稳定的原因, 并对金属卤化物钙钛矿LED研究面临的挑战和未来发展方向进行了总结与展望.     

聚集诱导发光有机小分子无机纳米复合材料的研究进展

有机-无机复合荧光纳米材料制备简便,生物相容性好,成像性能优异,在化学和生物传感、生物成像、催化及能源材料等领域受到很多关注.传统的荧光有机小分子与无机材料复合时,常发生荧光猝灭,而聚集诱导发光(Aggregation-InducedEmission,AIE)有机小分子在聚集态具有高发光量子产率,为有机-无机复合荧光纳米材料的研究提供了机遇.由于AIE有机小分子功能化的无机纳米材料独特的优点,人们对其设计、合成及应用进行了较多研究.综述了AIE有机小分子和多种类型的无机纳米结构(金属纳米颗粒、钙钛矿材料、层状材料、氧化物、硫化物等)复合材料的制备和应用的新进展,特别是在化学和生物传感、生物成像、药物输运、光热治疗、催化以及能源等领域的应用,并对其发展前景进行了展望.     

有机、聚合物薄膜电致发光器件的研究进展

有机、聚合物薄膜电致发光器件是近年来国际上的一个研究热点。与无机材料相比, 有机材料具有更高的发光效率和更宽的发光颜色选择范围, 并且具有容易大面积成膜的优越性。本文介绍了有机、聚合物薄膜电致发光器件的结构和制备、发光机理以及有关材料的选择, 并对该研究领域的最新动态、器件的稳定性问题以及应用前景进行了讨论。     

阴极界面修饰层改善平面p-i-n型钙钛矿太阳能电池的光伏性能

有机/无机杂化金属卤化物钙钛矿半导体材料结合了有机材料良好的溶液可加工性以及无机材料优越的光电特性,近几年受到了热捧,成为太阳能电池领域一颗耀眼的明星. 伴随着钙钛矿薄膜结晶过程和形貌的优化、器件结构的改进以及电极界面材料的开发,这类有机/无机杂化金属卤化物钙钛矿太阳能电池的光电转换效率从最初的3.8%迅速提高到目前最高的22.1%. 其中界面工程在提升器件性能上发挥着极其重要的作用. 本文总结了平面p-i-n型钙钛矿太阳能电池中阴极界面修饰层（CBL）的研究进展. CBL从材料上讲可分为无机金属氧化物、金属或金属盐以及有机材料,从构成上讲可分为单层CBL、双层CBLs以及共混型CBL. 本文对这些类型的CBL分别给予详细的介绍. 最后,我们归纳出CBL在改善器件效率和稳定性上所起的作用以及理想CBL所应满足的要求,希望能为以后阴极界面修饰材料的设计提供一定的借鉴.     

圆偏振热活化延迟荧光材料及其器件的研究进展

圆偏振热活化延迟荧光材料具有分子结构易修饰、激子利用率高及圆偏振发光等特点,在光学信息存储、3D显示、发光器件和数据加密等领域具有广阔应用前景.利用此类材料作为发光层制备的圆偏振有机发光二极管,能够同时实现高发光不对称因子和理论上达100%的激子利用率,对发展低功耗和高性能有机发光二极管至关重要.近年来,通过不断的分子结构设计与优化,该类材料在有机发光二极管中的电致发光效率不断提高,但是仍然存在不对称因子低及效率滚降严重等问题.基于此,整理了目前已报道的圆偏振热活化延迟荧光化合物,重点讨论了其分子结构设计与光物理性质、圆偏振特性以及电致发光性能的关系规律,并对高性能圆偏振热活化延迟荧光材料的制备及其在有机发光二极管中的应用进行了展望.     

有机、无机及纳米复合荧光材料的研究进展

本文通过总结分析当今发光材料研究进展,阐述了有机、无机荧光材料的特点并对主要荧光材料的最新进展进行概述。重点分析了以介孔材料为载体的复合荧光材料的优点及其研究现状与进展。     

两亲8-氨基喹啉衍生物的空穴传输特性及LB膜电致发光器件

在过去的20年里,电致发光(EL)领域的研究显得异常活跃,EL已应用于通讯、信息、显示等许多领域,而占领这一领域的是P-N结无机半导体发光二级管,其发光效率已超过了白炽灯.但由于无机半导体很难实现大面积平面显示,加之成本较高,因此,限制了其进一步的发展[1].有机荧光材料的种类繁多,荧光量子效率高,且可以通过分子结构修饰有目的地控制其发光效率、发光颜色和电学性能[2],因而,越来越多的学术界和工业界的研究小组进入了有机电致发光研究领域[3.4].     

三重态发光材料Cu4掺杂的PVK发光器件及特殊的发光增强机理研究

多种有机发光材料已被应用于电致发光（EL）器件的制备,其荧光效率远比无机发光材料高。与光激发直接产生单重态洋鬼子不同,电致发光过程是电子空穴分别由相反极性的电极注入（非成对电子注入）,三重态和单重态激子同时生成,按自旋统计理论预测,三重态和单重态子的比例为3：1。由于三重态的跃迁是自旋禁阻的,大部分有机分子的三重态激子发光效率极低,有机电致发光器件的最高交率限制在25％（对于光致发光效率100％的理想情况）。为进一步提高器件效率,人们开始设想和实施对通常认为是无效激发的75％的三重激发态进行利用,其关键是筛选出适于器件应用的高效率三重态发光材料,据此我们选择过渡金属配合物Cu4(C≡CPh4)4L2[L=1,8-bis9diphenyl phosphino)-3,6-dioxaoctane]（以下简称Cu4）进行了器件性能研究。     

蓝光热激活延迟荧光分子设计策略概述

热激活延迟荧光（thermally activated delayed fluorescence,TADF）分子由于三重态上的激子可以通过反向系间窜越到单重态并辐射发出荧光，因此在有机发光二极管（organic lightemitting diode, OLED）中理论上可以实现100%的激子利用率。具有TADF特性的发光材料融合了第一代荧光材料和第二代磷光材料的优点，不仅可以实现100%的内量子效率，还有助于降低器件的材料成本，被誉为第三代OLED发光材料，并成为突破高效稳定蓝光OLED瓶颈的潜在解决方案。本文从发光机理出发，系统阐述了高效稳定蓝光TADF分子的设计策略，包括高荧光量子产率、短延迟荧光寿命、窄发射光谱半峰宽、显著的水平分子取向和良好的光电稳定性等。本文旨在为高性能蓝光TADF分子的开发提供理论支持。最后，总结了当前蓝光TADF材料存在的问题，并对其未来的发展前景进行了展望。     

Recent progress of electronic materials based on 2,1,3-benzothiadiazole and its derivatives: synthesis and their application in organic light-emitting diodes

2,1,3-Benzothiadiazole(BT) and its derivatives are very important acceptor units used in the development of photoluminescent compounds and are applicable for the molecular construction of organic light-emitting diodes, organic solar cells and organic field-effect transistors. Due to their strong electron-withdrawing ability, construction of molecules with the unit core of BT and its derivatives can usually improve the electronic properties of the resulting organic materials. In this contribution, we review the synthesis of various polymers, small molecules and metal complexes with BT and its derivatives and their applications in organic light-emitting diodes. Furthermore, the molecular design rules based on these cores are discussed.     

溶胶-凝胶法制备有机/无机杂化材料工艺及其应用

介绍了溶胶–凝胶法制备有机/无机杂化材料的原理和基本过程,杂化材料的制备方法及对材料性能的影响,概述了杂化材料在结构材料、光学材料及其它材料中的应用研究。     

Research progress on hybrid organic-inorganic perovskites for photo-applications

Hybrid organic-inorganic perovskite materials have attracted significant attention of most researchers in recently years, which is ascribed to the superior photoelectric properties, such as the suitable band gaps for harvesting sunlight, and exhibit high optical adsorption, high charge-carrier lifetimes and long diffusion lengths. The photodetectors, light-emitting diodes, solar cells and photocatalysts represent the remarkable applications for the hybrid organic-inorganic perovskite materials. Herein, we review the recent progress of hybrid organic-inorganic perovskite-based photodetectors, light-emitting diodes, solar cells and photocatalysts. The challenges and outlook for the hybrid organic-inorganic perovskite-based photodetectors, light-emitting diodes, solar cells and photocatalysts are considered.     

New Strategy for Optimizing the Properties of Copper Halide Organic-Inorganic Hybrid Lighting-emitting Materials

Copper(I) halide organic-inorganic hybrid luminescent materials have many advantages, such as diverse structure, facile synthesis, high luminescent efficiency, tunable optical performance, etc., and show a broad application prospect in energy-saving lighting, display and other fields. However, compared with commercial rare-earth-metal-based phosphors, the reported hybrids generally suffer from poor stability and low luminescent efficiency, which are the bottleneck problem of their practical application. With the aim of developing high-performance organic-inorganic hybrid luminescent materials, a new synthesis strategy has been reported. This strategy can systematically design and synthesis copper(I) halide ionic hybrid structures by combining the covalent bonding and ionic bonding between inorganic and organic components into one structure, and use their synergistic effect to optimizing their properties. This design method is expected to develop high-performance organic-inorganic hybrid luminescent materials, promote the in-depth understanding of this field, and provide new ideas for the optimization of other types of hybrid materials.     

Recent Advances and Optoelectronic Applications of Lead-Free Halide Double Perovskites

Organic–inorganic metal halide perovskites (most notably CH₃NH₃PbI₃) have demonstrated remarkable physical attributes for photovoltaic and diverse optoelectronic applications, whereas concerns about toxicity owing to the use of lead in the chemical composition still motivate further exploration of new, nontoxic candidates. Lead-free halide double perovskites (HDPs), designed by the rational chemical substitution of Pb²⁺ with other nontoxic candidate elements, have recently attracted interest as a fascinating alternative to their Pb-based counterparts. Herein, recent advances in crystal structures, physical properties, and versatile optoelectronic applications of lead-free HDPs, such as solar cells, photodetectors, X-ray detectors, and light-emitting diodes, are reviewed. Perspectives to improve the physical and photoelectric properties of existing HDP materials are also discussed and will favor future development of new, lead-free HDP candidates.     

锡钙钛矿太阳能电池的进展与展望

金属卤素钙钛矿是目前最有前景的高效低成本新型太阳能电池材料,但是目前还存在环境友好性和理论效率极限较低的问题。锡钙钛矿环境友好,而且其带隙更窄理论转换效率更高,吸引了广泛的关注。锡钙钛矿太阳能电池(TPSC)近年来发展迅速,是目前效率最高的无铅钙钛矿太阳能电池。本文先介绍了锡钙钛矿的晶体结构、能带结构和光电性质,然后总结了最近在锡钙钛矿领域有代表性的工作和提高光电转化效率的策略,最后讨论了锡钙钛矿发展面临的挑战和未来的发展方向。     

Luminescent Organic-Inorganic Hybrid Metal Halides: An Emerging Class of Stimuli-Responsive Materials

Luminescent organic-inorganic metal halides (OIMHs) are well known as a new materials family in recent years. Novel materials and applications of luminescent OIMHs have been explored by changing either the organic component or the metal halide species. Thereinto, the stimuli-responsive (SR) phenomena in OIMHs have drawn much attention recently, for not only their attractive application potential but also the helpfulness in understanding the stability of OIMHs to the external environment. Herein, the luminescent OIMHs that are sensitive to external stimuli including contact, pressure, mechanical grinding, light, heat, and gas molecules, are reviewed, with an emphasis on analyses of the structural change during the SR process. The applications of SR luminescent OIMHs in widespread fields, including gas sensing, information encryption, and rewritable luminescent paper are summarized. Finally, the challenges that deserve to be further explored in this research field are discussed, which provides certain guidance for the future study of SR luminescent OIMHs.     

Rational design of functional oxide thin films with embedded magnetic or plasmonic metallic nanoparticles

Getting into films: Semiconductor thin films containing magnetic or plasmonic metal nanoparticles are key materials for the development of high-efficiency solar cells, bright light-emitting diodes, and new magnetoelectric devices. The catalytically driven chemical vapor deposition offers a unique way to combine deposition of the metallic nanoparticles with that of functional oxides to produce such films.