长余辉发光材料在陶瓷行业的应用研究

长余辉发光材料和陶／搪瓷材料的结合始于80年代,当时采用的是传统的硫化物体系长余辉发光材料。20世纪90年代,随着多种新型长余辉材料的发现,使性能更佳的长余辉陶／搪瓷制品的开发成为可能。本文介绍新型铝酸盐体系、硅酸盐体系及新型红色长余辉材料应用于低温陶／搪瓷釉料（800－900℃）、中温陶瓷釉料（980－1100℃）,及将低温陶／搪瓷釉料、中温陶瓷釉料应用于陶／搪瓷制品的研究,以及将各种新型长余辉材料应用于花纸、玻璃行业中。这种长余辉陶／瓷制品性能稳定、发光强度达到发光粉的80％,发光时间可达12h以上;而且应用工艺简单,可直接用传统的陶／搪瓷制品工艺进行生产。     

稀土红色长余辉发光材料研究进展

综述了稀土元素掺杂红色长余辉发光材料的研究进展，总结了硫化物、钛酸盐、硫氧化物、硅酸盐、氧化物和磷酸盐等基质体系的红色长余辉发光，并指出硫氧化物和磷酸盐等基质是最具有发展前景的红色长余辉发光体系，讨论了Eu^2 在硫化物、Pr^3 在钛酸盐以及Eu^3 和Sm^3 等稀土离子在硫氧化物和硅酸盐等体系中的红色长余辉发光机制。介绍了传统的高温固相法以及溶胶．凝胶法、微波合成法等稀土红色长余辉材料的制备技术。提出了从基质材料、制备技术和稀土离子发光机制入手是稀土红色长余辉发光材料今后研究与开发的发展方向。     

长余辉发光材料研究进展

长余辉发光材料是一类重要的光-光转换和节能材料。这类材料在工农业生产、军事、消防和人们生活的许多方面得到广泛应用。本文主要结合本课题组近年在长余辉发光材料领域的研究工作,综述长余辉发光材料的研究进展,并对今后的发展方向进行展望。     

一种新的橙红色长余辉荧光材料Y2O2S∶Sm3+

铜激活的硫化锌(ZnS∶Cu)和铕激活的硫化钙(CaS∶Eu)是最早获得应用的蓝色和红色长余辉材料. 随后, 相继发现了铝酸盐体系和硅酸盐体系两大类长余辉荧光材料[1～3]. 这两类长余辉荧光材料在发光亮度、余辉时间、稳定性方面都较前述硫化物系列长余辉荧光材料有很大提高, 从而具有非常广阔的应用前景和应用范围[4～6]. 但这两类长余辉荧光材料的发光颜色一般为蓝紫、蓝或黄绿, 没有红色发光现象. 随着研究的深入, 人们发现了稀土元素激活的碱土钛酸盐红色长余辉荧光材料, 这种荧光材料在发光亮度及余辉上都有明显的提高[7,8], 而且解决了硫化物不稳定的缺点. 近年来才发展起来的以碱土金属氧化物为发光基质, 以Eu3+为激活剂的红色长余辉荧光材料进一步提高了余辉亮度及时间[9].     

碱土铝酸盐长余辉发光材料的有机包覆及其表征

碱土铝酸盐长余辉发光材料的有机包覆及其表征;发光粉;包覆;甲基丙烯酸甲酯;硅烷偶联剂     

长余辉光致发光聚甲基丙烯酸酯共聚物球粒的合成

过去仅用ＺｎＳ和ＣａＳ等的长余辉发光材料(发光时间只有十几分钟 )。加入少量Ｃｏ、Ｐｍ物质 ,发光时间延长 ,亮度提高 ,但Ｃｏ、Ｐｍ具有放射性。以铝酸盐为基料制备的发光材料发光时间 ,发光强度明显提高。铝酸盐掺杂少量稀土元素Ｄｙ、Ｅｕ ,制得发绿光的高亮度光致发光材料、余辉时间长达 1 5ｈ以上 ,而且该材料的使用寿命长 ,高达 1 0年以上[1 ] 。本文研制的发光球粒以甲基丙烯酸甲酯和丙烯酸乙酯为单体 ,少量的发光粉为关键组份 ,采用悬浮聚合方法合成得到。聚甲基丙烯酸甲酯(ＰＭＭＡ)具有优良的透明度、光泽度和强度 ,而且具有良…     

新型红色荧光粉Sr3Al2O6的合成和发光性能研究

稀土金属离子激活的多铝酸盐发光材料，在可见光区具有较高的量子效率犤１～４犦，充分显示出这类荧光发光材料，在高效节能、环保、电光源与新一代可见光显示器领域的应用前景犤４～９犦。特别是SrAl２O４∶Eu２＋的持续发光现象的发现犤２，３犦，激起了对以稀土金属离子为激活剂，碱土铝酸盐为基质的长余辉无机发光材料体系的兴趣。研究表明其发光强度和余辉时间是传统硫化物发光材料的十倍以上，利用其长余辉储光－发光特性，有望开发新型发光油漆、涂料、发光陶瓷、发光塑料、薄膜、发光纸、发光纤维犤４犦。早在七十年代，荷兰菲利…     

碱土金属铝酸盐系列长余辉磷光体的制备研究

研究了MAl2O4∶Eu2+(M=Ca,Sr,Ba)磷光体的制备过程,通过向磷光体中引入微量Dy3+,B3+等添加剂离子,得到了发绿色光的超长余辉磷光体,余辉发光初始亮度达4.8cd·m-2,激发停止50h后,其余辉发光仍清晰可见。制备出发紫色光、蓝色光及黄色光的碱土金属铝酸盐系列长余辉磷光体。分析了各磷光体发射光谱、激发光谱及余辉发光,讨论了磷光体的光谱移动以及Eu2+在碱土金属铝酸盐中的发光。     

Tb~(3 )在MO(M=Ca,Sr)中的长余辉发光

长余辉发光材料的研究与应用,已有近100年的历史,目前仍在许多领域中有着重要应用[1].此类材料与其他光致发光材料具有相同的发光性能,只是更注重其发光的衰减过程和热释光性能.如,ZnS:Cu作为黄绿色的长余辉发光材料,在1992年以前是余辉性能最好的长余辉发光材料,一直处于发光研究工作的中心.     

Tb3+在MO(M=Ca,Sr)中的长余辉发光

长余辉发光材料的研究与应用，已有近100年的历史，目前仍在许多领域中有着重要应用。此类材料与其他光致发光材料具有相同的发光性能．只是更注重其发光的衰减过程和热释光性能。如．ZnS：Cu作为黄绿色的长余辉发光材料，在1992年以前是余辉性能最好的长余辉发光材料，一直处于发光研究工作的中心。     

Benzimidazobenzothiazole‐Based Bipolar Hosts to Harvest Nearly All of the Excitons from Blue Delayed Fluorescence and Phosphorescent Organic Light‐Emitting Diodes

Much effort has been devoted to developing highly efficient organic light‐emitting diodes (OLEDs) that function through phosphorescence or thermally activated delayed fluorescence (TADF). However, efficient host materials for blue TADF and phosphorescent guest emitters are limited because of their requirement of high triplet energy levels. Herein, we report the rigid acceptor unit benzimidazobenzothiazole (BID‐BT), which is suitable for use in bipolar hosts in blue OLEDs. The designed host materials, based on BID‐BT, possess high triplet energy and bipolar carrier transport ability. Both blue TADF and phosphorescent OLEDs containing BID‐BT‐based derivatives exhibit external quantum efficiencies as high as 20 %, indicating that these hosts allow efficient triplet exciton confinement appropriate for blue TADF and phosphorescent guest emitters.     

Achieving White-Light Emission Using Organic Persistent Room Temperature Phosphorescence

Artificial lighting currently consumes approximately one-fifth of global electricity production. Organic emitters with white persistent RTP have potential for applications in energy-efficient lighting technologies, due to their ability to harvest both singlet and triplet excitons. Compared to heavy metal phosphorescent materials, they have significant advantages in cost, processability, and reduced toxicity. Phosphorescence efficiency can be improved by introducing heteroatoms, heavy atoms, or by incorporating luminophores within a rigid matrix. White-light emission can be achieved by tuning the ratio of fluorescence to phosphorescence intensity or by pure phosphorescence with a broad emission spectrum. This review summarizes recent advances in the design of purely organic RTP materials with white-light emission, describing single-component and host-guest systems. White phosphorescent carbon dots and representative applications of white-light RTP materials are also introduced.     

Utilizing d–pπ Bonds for Ultralong Organic Phosphorescence

Developing pure organic materials with ultralong lifetimes is attractive but challenging. Here we report a concise chemical approach to regulate the electronic configuration for phosphorescence enhancement. After the introduction of d–pπ bonds into a phenothiazine model system, a phosphorescence lifetime enhancement of up to 19 times was observed for DOPPMO, compared to the reference PPMO. A record phosphorescence lifetime of up to 876 ms was obtained in phosphorescent phenothiazine. Theoretical calculations and single‐crystal analysis reveal that the d–pπ bond not only reduces the (n, π*) proportion of the T₁ state, but also endows the rigid molecular environment with multiple intermolecular interactions, thus enabling long‐lived phosphorescence. This finding makes a valuable contribution to the prolongation of phosphorescence lifetimes and the extension of the scope of phosphorescent materials.     

Wide‐Range Color‐Tunable Organic Phosphorescence Materials for Printable and Writable Security Inks

Organic materials with long‐lived, color‐tunable phosphorescence are potentially useful for optical recording, anti‐counterfeiting, and bioimaging. Herein, we develop a series of novel host–guest organic phosphors allowing dynamic color tuning from the cyan (502 nm) to orange red (608 nm). Guest materials are employed to tune the phosphorescent color, while the host materials interact with the guest to activate the phosphorescence emission. These organic phosphors have an ultra‐long lifetime of 0.7 s and a maximum phosphorescence efficiency of 18.2 %. Although color‐tunable inks have already been developed using visible dyes, solution‐processed security inks that are temperature dependent and display time‐resolved printed images are unprecedented. This strategy can provide a crucial step towards the next‐generation of security technologies for information handling.     

Subtle structure tailoring of metal-free triazine luminogens for highly efficient ultralong organic phosphorescence

Highly efficient ultralong organic phosphorescence (UOP) based on a series of metal-free triazine luminogens was achieved via subtly structural tailoring of bromine substituted positions.Impressively,p-BrAT in solid state displayed high phosphorescence efficiency up to 9.7% with a long lifetime of 386 ms,which was one of the highest efficient UOP materials reported so far in metal-free compounds.     

Subtle structure tailoring of metal-free triazine luminogens for highly efficient ultralong organic phosphorescence

Ultralong organic phosphorescent materials have invoked considerable attention for their great potential in sensing, data encryption, information anti-counterfeiting and so forth. However, effective ways to achieve highly efficient ultralong organic phosphorescence (UOP) in metal-free organic materials remain a great challenge. Herein, we designed three isomers based on asymmetric triazines with various bromine substituted positions. Impressively, phosphorescence efficiency of p-BrAT in solid state can reach up to 9.7% with a long lifetime of 386 ms, which was one of the highest efficient UOP materials reported so far. Theoretical calculations further demonstrated that para-substitution exhibited the most effective radiative transition for triplet excitons. These results will provide an effective approach to achieving highly efficient UOP materials.     

Recent progress on pure organic room temperature phosphorescence materials based on host-guest interactions

Pure organic room temperature phosphorescence (RTP) has been attracting a lot interest recently. So far, many strategies have succeeded in achieving efficient organic RTP materials by increasing the rate of intersystem crossing (ISC) and suppressing non-radiative transitions. In supramolecular chemistry, the control and regulation of molecular recognition based on the role of the host and guest in supramolecular polymers matrix, has attracted much attention. Recently, researchers have successfully achieved room temperature phosphorescence of pure organic complexes through host-guest interactions. The host molecule specifically includes the phosphorescent guest to reduce non-radiative transitions and enhance room temperature phosphorescence emission. This review aims to describe the developments and achievements of pure organic room temperature phosphorescence systems through the mechanism of host-guest interactions in recent years, and demonstrates the exploration and pursuit of phosphorescent materials of researchers in different fields.     

Molecular hosts for triplet emitters in organic light-emitting diodes and the corresponding working principle

This paper summarizes the mechanism and routes for excitation of triplet emitters in dopant emission based phosphorescent organic light-emitting diodes (PhOLEDs), providing a comprehensive overview of recent progress in molecular hosts for triplet emitters in PhOLEDs. Particularly, based on the nature of different hosts, e.g., hole transporting, electron transporting or bipolar materials, in which the dopant emitters can be hosted to generate phosphorescence, the respective device performances are summarized and compared. Highlights are given to the relationships among the molecular structure, thermal stability, triplet energy, carrier mobility, molecular orbital energy level and their corresponding device performances.     

The phosphorescence nanocomposite thin film with rich oxygen vacancy: Towards sensitive oxygen sensor

Organic room temperature phosphorescent (ORTP) materials provide an exciting research direction for phosphorescent oxygen (O₂) sensors due to their high sensitivity and rapid response to O₂. However, most pure ORTP materials are tightly-packed aromatic compound crystals in a face-to-face manner, which largely prohibits effective O₂ diffusion for sensing. Thus, how to solve this contradiction still faces huge challenges. Here, the use of organic phosphorescent indicator carbon dots (CDs), inorganic matrix layered double hydroxides (LDHs) and polymers (PVA) successfully prepared an ultra-long RTP composite film whose phosphorescence decay intensity is linearly related to O₂ concentration. More importantly, the use of the abundant O₂ defects (Vo) on the surface of the inorganic matrix LDHs to adsorb O₂, which further accelerates the phosphorescence quenching of the thin film and improves the O₂ response. This strategy will provide the possibility to develop high-sensitivity phosphorescent O₂ sensors from a new perspective.     

Recent progress on pure organic room temperature phosphorescence materials based on host-guest interactions

The inclusion of specific organic phosphorescent guest molecules by the host molecules can reduce the nonradiative transitions and engender room temperature phosphorescence emission.