固溶体结构对Ca_(2-x)Sr_xZn_4Ti_(15)O_(36)∶Pr~(3+)发光性质的影响

0引言在绿色和蓝色长余辉发光材料达到应用程度之后,耐候性红色长余辉发光材料成为人们研究的重点。Eu3 、Sm3 激活的硫氧化物[1￣3]、Eu2 铝锶复合硫氧化物[4]和Y2O3∶Eu3 [5]等耐热耐水性红色长余辉材料被相继发现。Pr3 离子掺杂的碱土金属钛酸盐(M TiO3∶Pr,M=M g,Ca,Sr,Ba)是一种新型的红色长余辉发光材料。这种发光材料在615nm附近有很好的单色性红光发射。碱土金属钛酸盐基质化学性能稳定,已开始应用于场发射显示器(FE D)[6,7]。碱土金属钛酸盐是A BO3型化合物,具有钙钛矿结构。B all[8]曾通过在CaTiO3中掺入不同量的Sr2 …     

钛酸盐红色长余辉陶瓷的制备与表征

以高温熔融法制备了钛酸盐为基质的红色长余辉陶瓷,研究氧化物及稀土氧化物改变对陶瓷发光性能的影响,用荧光光谱仪及X射线衍射仪对所制备的陶瓷试样进行表征.结果表明:添加适当的氧化物可获得均匀的玻璃并显著改善陶瓷的发光性能,共掺杂稀土离子不改变Ca0.8Zn0.2TiO3:Pr3+的发光机制.其发射峰为位于617 nm的窄带峰,对应于Pr3+的1D2→3H4的跃迁发射.添加的氧化物及稀土氧化物不改变基质的晶格,主晶相为CaTiO3.     

（CaO）20．68（MgO）1．32（SiO2）4S2：Eu^2＋，Dy^3＋红光材料的制备与发光特性

研究了峰值波长651nm的红色发光材料（CaO）20.68（MgO）1.32（SiO2）4S2：Eu^2＋，Dy^3＋的制备及发光特性。通过XRD分析表明硫气氛中合成的材料为具有硫成分的硅酸盐相。红光发射带为硫元素进入晶格后在发光中心周围形成了类似长余辉材料CaS：Eu^2＋，Cl^-的局域结构。这也使材料具有了硫化物长余辉材料的发射光谱特征和硅酸盐材料高化学稳定性和高亮度的优点。热释光测量揭示它可能是一种潜在的红色长余辉材料。     

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].     

长余辉发光材料研究进展

90年代发现和发展起来的铝酸盐体系长余辉发光材料是一类重要的新 型能源材料和节能材料。本文主要综述了最近几年来铝酸盐体系中长人科辉发光研究进展。指出了氧化物体系长余辉发光材料的特点和优势,总结了新型长余辉发光材料的基质和激活剂种类、性质及其对稀土 离子 长余辉发光性能的影响和作用,概括了长余辉发光模型,并提出了今后研究和应用的发展方向。     

(CaO)20.68(MgO)1.32(SiO2)4S2∶Eu2+,Dy3+红光材料的制备与发光特性

研究了峰值波长651nm的红色发光材料(CaO)20.68(MgO)1.32(SiO2)4S2∶Eu2 ,Dy3 的制备及发光特性。通过XRD分析表明硫气氛中合成的材料为具有硫成分的硅酸盐相。红光发射带为硫元素进入晶格后在发光中心周围形成了类似长余辉材料CaS∶Eu2 ,Cl-的局域结构。这也使材料具有了硫化物长余辉材料的发射光谱特征和硅酸盐材料高化学稳定性和高亮度的优点。热释光测量揭示它可能是一种潜在的红色长余辉材料。     

激活CaO-MgO-SiO_2长余辉玻璃发光性质

报道了一种新型的Eu~(2+)离子激活硅酸盐玻璃,该玻璃组成为2CaO-MgO-3SiO_2-0.015Eu_2O_3(CMSE)。通过透射光谱、稳态荧光光谱、余辉光谱和热释光等技术手段对CMSE的发光性质进行了深入研究。研究发现CMSE可以被紫光和近紫外光激发,获得黄色长余辉发光。热释光曲线的分析表明,CMSE的长余辉性质主要来自于玻璃基质中陷阱深度为0.83 e V左右的定域能级。研究认为对CMSE发光性质的研究有利于开发新型稀土离子激活近紫外激发LED用硅酸盐玻璃发光材料。     

Eu3+在Ba2TiSi2O8中的发光

红色荧光材料主要有(碱土)硫化物体系[1,2],(碱土)钛酸盐体系[3,4],氧化稀土体系[5],硅酸盐体系[6]以及其它氧化物体系如MO∶Eu~(3 )(M=Ca、Sr、Ba)[7],SrAl2O4∶Eu~(2 )[8]等。在这些体系中,主要以Eu3 做激活     

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。     

H3BO3对微波等离子体法合成SrAl2O4:Eu2+,Dy3+的影响

采用微波等离子体法合成SrAl2O4：Eu^2＋ Dy^3＋长余辉发光材料,探讨了H3BO3的加入对材料的光谱性能、余辉性能、相组成结构、微观形貌的影响。结果表明,适量的添加助溶剂H3BO3,有利于增强材料的发光强度,延长余辉时间,但过量的添加反而会导致发光性能下降。本试验确定硼酸的最佳添加量为10％。综合检测分析结果推断,硼酸加入后在高温下大部分形成液相,并通过液相传质促进晶体生长,提高基质的结晶程度,同时促进稀土离子Eu^2＋,Dy^3＋进入晶格并使其分布更均匀;而少部分则会进入晶格发生B取代Al,引起晶体场畸变,从而提高了材料的发光强度和长余辉特性。     

掺杂铕和铽的卤硼酸盐荧光体的制备及光谱特征

采用高温固相法在空气中合成了一系列掺杂稀土离子的卤硼酸盐荧光体, 研究了其发光性质和基质组成对稀土离子共掺杂的荧光体发光性质的影响. 研究结果表明, 在Eu3+和Tb3+共掺杂的体系中存在电子转移, 因此出现了Eu3+, Eu2+和 Tb3+共存于同一基质共同发射的现象. Ce3+对Eu2+和Tb3+具有敏化作用, 可增强其发射强度. 基质的组成对稀土离子的发射峰位和发射强度有明显影响.     

Blue,green,red upconversion luminescence and optical characteristics of rare earth doped rare earth oxide and oxysulfide

The cold isostatic press pretreatment process was adopted to prepare fine rare earth oxysulfide up-conversion phosphors with spherical shape, narrow size distribution and high luminescence efficiency. The upconversion optical characteristics and brightness of the blue (Y2O2SYb,Tm), green (Y2O2S: Yb,Er), red (Y2O3Yb,Er) emitter were also investigated, and a novel method was successfully developed for the brightness measurement of upconversion luminescence (UPL). It is shown that a white color can be obtained by the appropriate mixture of these primary blue, green and red emissions components. The Er3 ions exhibit different upconversion mechanism in Y2O2S and Y2O3 host materials. The rare earth oxysulfide is an efficient upconversion matrix. The UPL brightness of Y2O2S: Yb,Er is 6.5 times higher than that of Y2O3: Yb,Er, and Y2O2S: Yb,Er shows UPL brightness of 1100 cd/m2 under 5.56 W/cm2 power density using a 980 nm laser diode.     

Preparation and Optical Characterization of Organoeuropium-Doped Silica Gels

Gels have been investigated as potential matrices for rare earth luminescence. The use of complexing ligands in the sol-gel synthesis of the rare-earth doped glasses has been suggested to improve the rare earth ion luminescence properties in these matrices due to the changes in the local environment experienced by the rare earth ion. In this work, transparent Eu3+-doped gels were prepared from Si(OCH3)4 and fluorinated and/or complex-forming Eu3+ precursors (Eu(fod)3, (CF3 SO3)3Eu, (CF3CO2)Eu · 3H2O, Eu(thd)3 and Eu(acac)3). Results of emission, fluorescence line narrowing and lifetimes studies of Eu3+-doped gels derived from Si(OCH3)4 and fluorinated/chelate Eu3+ precursors are presented. The results were interpreted in terms of the evolution of the Eu3+ fluorescence in systems varying from solutions to the gels densified to 800°C. Analysis of the fluorescence decays of the 5D0 state suggests that the use of the fluorinated Eu3+ precursors reduces the hydrophobic content in the silica gels matrices. FLN studies indicate that Eu3+ clustering occurred in all densified samples.     

Multi-walled carbon nanotube-based ternary rare earth (Eu3+, Tb3+) hybrid materials with organically modified silica-oxygen bridge

A series of ternary rare earth (Eu(3+), Tb(3+)) complexes are covalently coated to the 3-aminopropyltriethoxysilane functionalized multi-walled carbon nanotube (MWCNT) by a simple in situ sol-gel method by the bifunctional silylated monomer TTA-Si and TAA-Si (TTA-Si and TAA-Si are 3-(triethoxysilyl)propylisocyanate (TEPIC) modified thenoyltrifluoroacetone (TTA) and trifluoroacetylacetone (TAA), respectively). The resulting materials are characterized by Fourier transform infrared spectra, scanning electronic microscope, transmission electron microscope, thermogravimetric analysis, ultraviolet visible diffused reflection measure, photoluminescence spectra, and X-ray diffraction. The photoluminesce measurements indicated that these hybrids exhibit characteristic red and green luminescence originating from the corresponding ternary rare earth ion (Eu(3+), Tb(3+)). The luminescence quenching effect of MWCNT networks have been successfully restrained by coating a relatively thicker silica-oxygen-based organic-inorganic complex. Furthermore, the fluorescence lifetimes and emission quantum efficiencies of Eu(3+) hybrid materials are also determined.     

稀土N-苯基邻氨基苯甲酸-1,10-邻菲咯啉二元、三元配合物的合成、表征及其光物理性质

合成了几种新型的稀土(钆,铕,铽)的N-苯基邻氨基苯甲酸-1,10-邻菲咯啉的二元、三元配合物.以元素分析、红外光谱和紫外光谱进行了表征,确定了组成.同时以低温磷光光谱确定了配体的三重态能级为24330cm^-1,研究了配体与稀土离子的能级匹配.详细讨论了配合物的光物理性质如发光性能和配体与稀土离子之间以及有机配体之间的分子内能量传递机制,结果发现,铽的N-苯基邻氨基苯甲酸-1,10-邻菲咯啉配合物的发光性能良好.     

The Luminescence Properties and Intramolecular Energy Transfer of Rare Earth Complexes with Aromatic Carboxylic Acids

ＩｎｔｒｏｄｕｃｔｉｏｎＴｈｅｉｎｔｒａｍｏｌｅｃｕｌａｒｅｎｅｒｇｙｔｒａｎｓｆｅｒｐｒｏｃｅｓｓａｎｄｍｅｃｈａｎｉｓｍｏｆｒａｒｅｅａｒｔｈｃｏｍｐｌｅｘｅｓｗｉｔｈβ－ｄｉｋｅｔｏｎｅｓｈａｖｅｂｅｅｎｇｅｎｅｒａｌｙｓｔｕｄｉｅｄａｎｄａｃ...     

稀土硫化物—聚苯乙烯纳米复合材料的制备与表征

采用原位合成法制备了稀土硫化物—聚苯乙烯纳米复合材料 .通过荧光光谱、磁性、光电子能谱、透射电镜等手段对材料进行表征 .荧光光谱测试可见Eu3+ 的特征发射峰 ;磁性测试表明与H2 S反应后复合材料的饱和磁化强度降低 ;TEM测试表明反应后复合材料的微观结构发生了变化 .分析了产生上述变化的原因     

Covalently bonded assembly and photoluminescent properties of rare earth/silica/poly(methyl methacrylate-co-maleic anhydride) hybrid materials

Copolymer (MMA-co-MAL) of methyl methacrylate (MMA) and maleic anhydride (MAL) was prepared and grafted by 3-aminopropyltriethoxysilane (APES), which behaves as the structural precursor for functional bridge to assemble the covalently bonded systems through the coordination to rare earth ions (Eu³⁺, Tb³⁺) with carboxylic groups of maleic anhydride. On the other hand, 1,10-phenanthroline (phen) is engaged in a second functional ligand to sensitize the luminescence of RE³⁺ (rare earth ions) by intramolecular energy transfer process. Meanwhile, the cohydrolysis and copolycondensation processes happened between triethoxysilyl of modified copolymer (MMA-co-MAL-APES) and tetraethoxysilane (TEOS) with Si–O covalent bonds, resulting in the polymer-inorganic hybrids (phen-RE-MMA MMA-co-MAL-Si) exhibiting characteristic red or green emissions of Eu or Tb ions. Especially the luminescent quantum efficiencies of europium hybrid systems are estimated and discussed in detail.     

White-light-emitting long-lasting phosphorescence in Dy-doped SrSiO3

We report on a luminescent phenomenon in Dy³⁺-doped SrSiO₃ long-lasting phosphor. After irradiation by a 254-nm UV lamp for 5 min, the Dy³⁺-doped SrSiO₃ phosphor emits white light-emitting long-lasting phosphorescence for more than 1 h even after the irradiation source has been removed. Photoluminescence, long-lasting phosphorescence and thermoluminescence (TL) spectra are used to explain this phenomenon. Photoluminescence spectra reveal that the white light-emitting long-lasting phosphorescence originated from the two mixtures of Dy³⁺ characteristic luminescence, the 480-nm blue emission (⁴F_9/2→⁶H_15/2) and the 572-nm yellow emission (⁴F_9/2→⁶H_13/2). TL spectra shows that the introduction of Dy³⁺ ions into the SrSiO₃ host produces a highly dense trapping level at 377 K (0.59 eV), which is responsible for the long-lasting phosphorescence at room temperature. A possible mechanism of the long-lasting phosphorescence based on the experimental results is proposed. It is considered that the long-lasting phosphorescence is due to persistent energy transfer from the electron traps to the Dy³⁺ ions, which creates the persistent luminescence of Dy³⁺ to produce the white light-emitting long-lasting phosphorescence.