Chiral thermally activated delayed fluorescence materials for circularly polarized organic light-emitting diodes

Chirality is an important natural characteristic of organic molecules,and chiral organic molecules have shown extensive application in areas such as pharmaceutical development and material science.Benefiting from the ability to achieve circularly polarized luminescence(CPL),chiral luminescent materials have shown potential applications in anti-glare display,optical communication and,3D display,etc.Due to the ability to harvest both singlet and triplet excitons by a fast reverse intersystem crossing process without involving noble metals,chiral thermally activated delayed fluorescence(TADF)materials with point chirality,axial chirality,planar chirality and helical chirality are regarded as the state-of-the-art materials for circularly polarized organic light-emitting diodes(CP-OLEDs).In recent years,the chiral TADF materials and CP-OLEDs have rapidly developed,but unfortunately,the dissymmetry factors(g)are far from the requirement of practical applications.The ideal emitters and devices should have both high efficiency and a g factor,or at least a balance between these two elements.This review gives an overview of recent progress in chiral TADF materials,with a particular focus on the chiral skeleton,CPL property and device performance.Furthermore,the molecular design concept,device structure and methods to improve the g factors of chiral materials and CP-OLEDs are also discussed.

Synthesis of Pyrazolines Used as Blue Organic Electroluminescence Materials

Three kinds of pyrazolines were designed and synthesized. Their structures were elucidated by IR, (HNMR)-H-1, MS, UV and elemental analysis. Their luminescent properties were determined, which indicated that they had strong blue fluorescent properties. One of them was designed to have good film formation. All the three kinds of pyrazolines can be used as blue organic electroluminescence materials (OELMs).

Synthesis and Color-tunable Fluorescence Properties of Schiff Base Zinc (II) Complexes Used as Electroluminescent Materials

Four kinds of bis(N-alkylsalicylaldiminato) zinc(II) complexes were synthesized, and their molecular structures were determined by FT-IR and elemental analysis. Their photoluminescence properties were determined, which indicated that they could emit strong fluorescence varying from blue to yellow to reddish orange depending on their different molecular structures. They had good thermostability, solubility and film forming capability, and can be used as organic lectroluminescent materials. These new complexes may afford the feasibility to realize full-color display with materials based on similar molecular structures.

高湿度下具有荧光指示功能的PET复合膜的制备与性能

为了制备出能在高湿度、易结雾环境下可持续发光的薄膜,以聚对苯二甲酸乙二醇酯(PET)膜为基底,将具有优异疏水功能的新型稀土发光配合物和聚甲基丙烯酸甲酯(PMMA)均匀分散制成发光涂覆液,通过涂覆刮膜技术,制备出PET-PMMA发光复合膜,并对其进行测试表征。荧光分光光度计和共聚焦显微镜测试的结果表明:发光材料占聚合物PMMA的质量分数为1.50%时所制备的PET发光膜具有良好的表面均匀性和最佳的荧光性能,荧光强度可达到9979 a.u.,在不同激发波长下PET-PMMA发光复合膜均可以显现出发光材料中Eu3+的特征荧光发射峰;测得发光复合膜的最佳紫外激发波长为350 nm,在最佳激发波长下发光复合膜具有较好的色纯度;通过对比发光复合膜浸泡在水溶液7 d内每天的荧光强度值,发现在发光材料仅有1.50%的前提下,样品的荧光强度损失仅有5%,这表明所制备的发光复合膜遇水易猝灭的弊端得到极大改善,这为PET农膜在潮湿、易结雾环境下实现长期稳定的荧光指示功能提供了重要基础。

基于蓝光TADF材料的敏化白光OLED特性

白光有机发光二极管(WOLEDs)由于面光源、可柔性、轻薄、自发光等优势而广泛应用于显示和照明领域。目前,高效溶液处理的混合白光有机发光二极管很少被报道。本文选择蓝色热致延迟荧光材料DMAC-DPS作为传统橙色磷光材料PO-01-TB的敏化主体,制备了热活化敏化的杂化单发光层有机发光二极管白光器件,分析了器件能量传递机制。通过主客体掺杂浓度调控,实现了外部量子效率最高为8.00%、电流效率为22.32 cd/A、对应CIE坐标(0.405,0.497)及色温为4059 K的暖白光OLED器件,增加空穴阻挡层DPEPO有效地提高了器件的光谱稳定性,实现了更小的ΔCIE(0.017,0.016)。

新型有机荧光材料设计机理

从发光机理上综述了热活化延迟荧光和杂化局域–电荷转移态两类有机荧光材料的设计理念,以期为现阶段有机荧光材料的设计和开发带来新思路和启示。

基于蒽[2,3⁃b]苯并呋喃为核心的高效长寿命蓝光材料

设计合成了一种以蒽[2,3-b]苯并呋喃为核心的新型化合物,通过给体咔唑基团修饰得到化合物2-(蒽[2,3-b]苯并呋喃-3-基)-9-苯基-9H-咔唑(ABPCz)。经过掺杂器件研究,ABPCz可以实现蓝光发射,最大电流效率为8.79 cd/A,最大外量子效率为7.8%,CIE(0.17,0.23),峰值光谱448 nm,在476 nm处有较强的肩峰,在1000 cd/m2初始亮度下测试器件LT90(亮度衰减到初始亮度的90%)寿命达到153 h。结果表明,蒽[2,3-b]苯并呋喃经过咔唑基修饰可以得到高效、长寿命的蓝光器件,这为设计开发高性能蓝光材料提供了一个新途径。

锌金属有机骨架材料在食品Fe^(3+)检测中的应用

以2,2',5,5'-偶氮苯四羧酸(ABTC)、1,2,4-三氮唑(Tz)和硝酸锌为原料合成的一种锌金属有机骨架材料([(CH_(3))_(2)NH_(2)][Zn_(2)(ABTC)(Tz)]·3DMF)作为研究对象,用荧光光谱法对该材料的荧光特性进行探究。测试结果显示,相较于其他离子而言,Fe^(3+)离子的样品溶液发光强度猝灭效果最为明显,并且Zn-MOF材料对Fe^(3+)离子有良好的猝灭效果和选择性。利用Zn-MOF材料的这一特性,在实验中以Zn-MOF材料作为荧光探针来测定食品(紫菜、猪肝粉、奶粉、核桃和牛肉)中Fe^(3+)的含量。

Progress in small-molecule luminescent materials for organic light-emitting diodes

Organic light-emitting diodes （OLEDs） have been extensively studied since the first efficient device based on small molecular luminescent materials was reported by Tang. Organic electroluminescent material, one of the centerpieces of OLEDs, has been the focus of studies by many material scientists. To obtain high luminosity and to keep material costs low, a few remarkable design concepts have been developed. Aggregation-induced emission （AIE） materials were invented to overcome the common fluorescence-quenching problem, and cross-dipole stacking of fluorescent molecules was shown to be an effective method to get high solid-state luminescence. To exceed the limit of internal quantum efficiency of conventional fluorescent materials, phosphorescent materials were successfully applied in highly efficient electroluminescent devices. Most recently, delayed flu- orescent materials via reverse-intersystem crossing （RISC） from triplet to singlet and the ＂hot exciton＂ materials based on hy- bridized local and charge-transfer （HLCT） states were developed to he a new generation of low-cost luminescent materials as efficient as phosphorescent materials. In terms of the device-fabrication process, solution-processible small molecular lumi- nescent materials possess the advantages of high purity （vs. polymers） and low procession cost （vs. vacuum deposition）, which are garnering them increasing attention. Herein, we review the progress of the development of small-molecule luminescent materials with different design concepts and features, and also briefly examine future development tendencies of luminescent materials.

A Fluorescence Ratiometric Probe for Detection of Cyanide in Water Sample and Living Cells

In the present work, Compound 1 has been synthesized as a novel fluorescence ratiometric probe for CN-. Upon treatment with CN-, Probe 1 exhibited a fluorescence ratiometric response, with the emission wavelength shift from 570 nm to 608 nm. When 90 μM CN-?was introduced, the emission ratios (I570/I608) of the probe changed dramatically from 0.52156 to 4.21472. The detection limit was also measured to be 0.24 μM (S/N = 3). In addition, Probe 1 had a selective response to CN-, while other anions caused nearly no interference. The sensing reaction product of Probe 1 with CN-?was characterized by 1H NMR spectra and ESI Mass spectrometry. Furthermore, Probe 1 has been successfully applied to detect CN-?in natural water samples. The fluorescence imaging experiments in living cells also demonstrated that Probe 1 could monitor CN-?in biological samples.

亚胺型共价有机框架材料制备及荧光增强检测Al^(3+)研究

以2,5二甲氧基对苯二甲醛和2,4,6-三(4-氨基苯基)-1,3,5-三嗪为原料,通过溶剂热法制备出亚胺类共价有机框架材料DmaTAPT。采用X-射线粉末衍射、C13固体核磁等方法对其结构进行表征,考察其在荧光检测Al^(3+)中的应用并对检测机制进行研究。结果表明,基于光生电子转移荧光增强机制,对Al^(3+)检测限为1.82×10^(-5)mol/L,可以作为荧光传感器实现对Al^(3+)的高效检测。

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 light-emitting 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。

小分子有机荧光材料在重金属离子检测中的应用研究进展

小分子有机荧光材料由于具有种类众多、结构可调、荧光量子效率高、选择性好和光谱可调节等优点,被广泛应用在环境监测、医学成像等领域。对环境中重金属离子的检测具有高选择性、高灵敏性和良好的稳定性等优势,成为了常用的重金属离子检测方法之一。综述了近年来有机小分子荧光材料应用于环境中汞、铅、铁等金属离子检测的研究进展,介绍了多种荧光探针的合成、反应现象、传感机制、检测能力及实际应用等,并对其发展趋势及应用进行了展望。

基于功能化MOFs气敏材料结合荧光光谱技术检测冷鲜猪肉新鲜度的可行性研究

金属有机骨架材料(MOFs)是一类高比表面积、结构多样性、可修饰性较强的无机配位多孔骨架材料,在挥发性有机化合物的吸附、传感等领域有巨大应用前景。新鲜度的评价对于肉类工业发展具有重要意义,肉类在品质劣变时会产生挥发性物质,是指示其新鲜度变化的灵敏的信息。据此,研究制备了一种基于荧光传感的冷鲜猪肉新鲜度指示MOFs复合膜,并且依据膜对劣变挥发性化合物的响应信息、对应猪肉样品的新鲜度指标(TVB-N值)建立PLS定量分析模型,证实其有望成为冷鲜肉品质劣变监测的新技术。主要结论如下:以六水硝酸锌∶对苯二甲酸=2∶1的比例,并向其中添加浓度为2×10^(-3)mol·L^(-1)的罗丹明B,制备得到RhB@MOF-5,并对其进行表征。根据RhB@MOF-5吸附冷鲜猪肉劣变气味前后的红外光谱变化,推测其中可能有胺类物质。之后以MOF∶PVDF(w/w)=4∶5的比例按照混合基质法制得MOFs复合薄膜。并通过贮藏期实验验证了MOFs复合膜的贮藏稳定性,证明其能在4℃避光环境中维持至少60 d的荧光稳定性。此外,利用MOFs复合膜结合荧光传感技术对冷鲜猪肉整个劣变期间的挥发性化合物进行吸附、响应,观察其荧光性质的变化。同时采用三维荧光技术观察到吸附后MOF-5相关峰和罗丹明B相关峰强度减弱,分析是由胺类物质引起的罗丹明B电子云改变,从而产生荧光猝灭。采集激发波长340 nm处的表面荧光光谱可同时得到两个发射波长分别为435nm和550nm的特征峰与TVB-N值的响应信息,使用偏最小二乘算法(PLS)建立新鲜度指标(TVB-N)预测模型,建模结果R_(c)^(2)为0.908,R_(p)^(2)为0.821,RMSEC和RMSEP分别为3.435和3.647 mg·(100 g)^(-1),具有良好的预测精度。表明功能化MOFs复合膜可用于冷鲜猪肉的新鲜度预测。

有机小分子荧光材料的前生今世

近年来,有机发光二极管(OLED)显示屏随着智能手机的普及,逐渐被大众熟知,而用以制备OLED发光显示层的有机荧光材料,其研发过程也吸引了更多研究者的视线。本文按照时间顺序,对有机小分子荧光领域几个重要的发现进行了回顾,以通俗易懂的语言介绍了有机小分子荧光材料的发展过程及一些相关概念。

1,2-二咔唑基-4-溴苯的合成及长余辉性质表征

有机功能材料是有机化学重要的研究方向之一。将国际前沿的先进有机功能材料合成方法及其性质表征引入到基础有机化学实验,有望进一步丰富教学内容,促进本科教学与科研成果之间的衔接。基于此目的,本项目选择有机长余辉材料这一国际前沿研究热点,与芳香亲核取代反应实验教学相结合,指导学生认识合成反应在构建有机功能材料中的关键作用,进一步将知识体系延伸至现代波谱技术,树立学生正确的科学观念。通过本项目,形成“有机反应-分子结构-材料功能”为链条的系统教学,培养学生的科学素养和综合创新能力。

有机共轭聚合物荧光材料在重金属离子检测中的应用研究进展

有机荧光共轭聚合物含有离域大π键,电子或能量可以在共轭聚合物主链上快速迁移,这一“分子导线”性质可使荧光信号成倍增大。此外,有机荧光共轭聚合物还具有较大的斯托克位移、良好的稳定性、较高的摩尔消光吸收系数等优点。通过合理设计,将金属离子识别基团键合至有机荧光共轭聚合物,得到的有机共轭聚合物荧光材料比小分子荧光材料更具优势。有机共轭聚合物荧光材料有多种合成方法,从反应合成类型的角度,结合设计理念、传感应用及检测机理等,综述了近年来有机共轭聚合物荧光材料应用于重金属离子检测的研究进展,并对其发展趋势进行了展望。

过渡金属配合物TADF发光材料研究进展

高效率利用三重态激子发光是制备高性能有机发光二极管(OLED)的关键。除磷光过渡金属配合物外,具有热活化延迟荧光(TADF)特性的过渡金属配合物能够将三重态激子上转换为单重态激子,进而通过单重态激子辐射发光,为开发金属配合物发光材料提供了新的途径。然而,过去十年来OLED发光材料的研究主要聚焦在纯有机TADF体系上,过渡金属配合物TADF材料的研究投入相对偏少。但是,已有研究表明金属配合物能够利用金属的重原子效应促进反向系间窜越(RISC)过程,提升TADF发光效率并缩短TADF寿命,有利于制备高效率、低滚降的OLED。本文根据金属中心不同的d电子构型分类筛选了TADF金属配合物研究领域中代表性的材料体系,对其激发态属性、光物理和器件性能进行了概括和讨论。通过对不同类型的TADF金属配合物发光性能的归纳和比较,揭示了金属中心和配体结构对配合物发光性质的影响规律,对进一步开发高性能的金属配合物TADF材料,尤其是基于廉价金属元素的TADF配合物具有重要的指导意义。

红光区双效发光材料BODIPY的制备及其光谱性质

通过吲哚衍生物与1,8-萘内酰亚胺缩合及氟硼化反应,得到meso位无取代和甲基取代的两种配体(Ⅰ、Ⅲ)及两种氟硼二吡咯(BODIPY)染料(Ⅱ、Ⅳ)。其结构和光学性能经NMR、HRMS、单晶、UV-Vis吸收光谱、荧光发射光谱和固体荧光光谱进行了表征。结果表明,meso位引入甲基后配体Ⅲ较配体Ⅰ的固体荧光发射峰红移了34 nm。BODIPY染料具有较强的双效荧光(溶液和固体荧光),其中BODIPY染料Ⅳ的溶液和固体荧光量子产率分别高达65.8%和76.3%,其固体荧光量子产率较meso位无取代BODIPY染料Ⅱ(14.6%)提高了4.2倍。BODIPY染料Ⅳ较强的双效发光可归因于其固体堆积方式中无C—H…π作用以及层与层之间存在的“头-尾”π-π堆积。不同于其他提高固态荧光的策略,在母体meso位引入小位阻甲基的策略使BODIPY具有双效红光发射性能,也丰富了双效有机发光材料的种类。

具有非对称性结构的咔唑修饰硼氮窄发射热活化延迟荧光材料的合成和性质研究

构建高性能的绿光、红光窄发射多重共振热活化延迟荧光材料是当前发光材料研究的热点和难点。通过在硼氮骨架的间位上引入咔唑给体基团,构建了兼具多重共振荧光特征和分子内电荷转移态的荧光材料mBNCz,咔唑基团的引入提高了分子的HOMO能级,分子的荧光发射峰发生显著红移。同时,化合物具备窄的荧光发射光谱、良好的热稳定性、高的荧光量子产率和显著的热活化延迟荧光特征,在发光显示材料中具有较高的应用潜力。