Tm3+掺杂锗镓酸盐玻璃的2 μm中红外光谱特性

用高温熔融法制备了Tm2O2掺杂浓度分别为1.526%,3.006%,5.836%,11.028%,15.678%(质量分数,以下同)的65GeO2-12Ga2O3-10BaO-8Li2O-5La2O3(摩尔比)玻璃.从其吸收光谱特性出发,应用Judd-Ofelt理论,计算了Tm3+离子的J-O强度参数(Ω2,Ω4,Ω6)及Tm3+离子各激发态能级的自发跃迁几率、荧光分支比以及辐射寿命等光谱参量.在808 nm波长光的激发下,研究了不同Tm3+掺杂浓度玻璃在～1.47 μm与～1.8 μm的荧光特性,发现当Tm2O3掺杂浓度约达到～3.006%时,在1.8 μm处的荧光强度达最大;然后随着掺杂浓度的增大,其荧光强度反而降低.本文从Tm3+离子间的能量交叉弛豫效应与浓度猝灭效应解释了这一荧光强度变化的现象.同时,根据Mc-Cumber理论,计算了Tm3+离子能级3F4→3H6(1.8 μm)跃迁的吸收截面和受激发射截面,该荧光的受激发射截面峰值比氟锆铝酸盐玻璃大.由于该玻璃材料表现出较好的光谱性能,因此该材料可望成为～2.0 μm波段中红外光纤激光器的候选基质材料.     

掺Nd3+碲酸盐玻璃光谱性质的研究

制备了Nd3+掺杂的碲酸盐玻璃, 测量了试样的吸收光谱、发射光谱, 计算了碲酸盐玻璃中Nd3+离子的强度参数(Ω2, Ω4, Ω6), 给出了Nd3+离子的发光特性(A, β, τrad, σ)的计算结果, 研究了其荧光特性、浓度淬灭及其机制. 研究发现组分70TeO2-20ZnO-(10-x)La2O3-xNd2O3(%,摩尔分数)碲酸盐玻璃具有高的发射截面和低声子能的特性. 当x为0.5时荧光强度和发射截面最大, 即在碲酸盐玻璃中Nd3+的最佳掺杂浓度为0.5%(1.93×1020 ions·cm-3). 碲酸盐玻璃中Nd3+离子实测荧光特性与计算结果基本一致.     

Er^3＋掺杂TeO2-WO3-ZnO—ZnF2玻璃的光谱性质

制备了Er^3 离子掺杂的TeO2-WO3-ZnO-ZnF2(TWZOF)玻璃，测试了样品的吸收光谱和970nmLD激发下样品中Er^3 离子的荧光光谱与荧光寿命，计算了Er^3 离子的J—O强度参数Ωt(t=2，4，6)和1．5μm波段的吸收截面与发射截面，研究了Er^3 离子1．5μm发射强度、荧光寿命和发射带宽与玻璃中ZnF2含量的关系。实验得到Er^3 离子在TWZOF玻璃中1．5μm发射的最大荧光半高宽(TwHm)为83nm；随着ZnF2含量的增加，Er^3 离子1．5μm发射强度、荧光寿命均增加。     

用于1．54μm微片激光器的高Er^3＋／Yb^3＋共掺杂的氟铝酸盐玻璃

本文系统制备了980nm半导体崩浦的应用于1．54μm波段微片激光器的高Er^3 ／Yb^3 共掺杂的氟铝酸盐玻璃。通过玻璃的吸收光谱，发射光谱和上转换荧光光谱的测试，对其光学性质、浓度淬灭及其淬灭机制进行了分析和讨论。当玻璃中Er^3 离子掺杂浓度低于10mol％的情况下，浓度淬灭现象较弱，Er^3 ／Yb^3 共掺杂的氟铝酸盐玻璃在由于Er^3 离子^4 I13／2→4^I 15／2跃迁所引起的1．54μm波段的发射强度比Er^3 单掺杂的氟铝酸盐玻璃中的荧光强度要强。在Er^3 离子掺杂浓度高于10mol％的情况下，由于Er^3 与Yb^3 之间的反能量转移过程，Er^3 ／Yb^3 共掺杂的氟铝酸盐玻璃的1．54μm波段的荧光浓度淬灭效应比Er^3 离子单掺杂的情况下明显。在Er^3 离子掺杂浓度小于10mol％的情况下，实验中发现可获得1．54μm波段高发射效率的Er^3 与Yb^3 离子最佳摩尔浓度掺杂比例约为1：1。     

Tm3+/Yb3+共掺氧氯碲酸盐玻璃上转换发光研究

制备了Tm^3＋/Yb^3＋共掺氧氯碲酸盐玻璃, 研究了玻璃的热稳定性能、 Raman光谱和上转换发光光谱, 分析了上转换发光机制. 结果表明： 通过980 nm的激光二极管激发, 在室温下同时观察到强烈的蓝光（476 nm）和微弱的红光（649 nm）, 分别是Tm^3＋离子的1G4→3H6和1G4→3H4跃迁. 随氯化铅含量增加, 基质玻璃的热稳定性能增强, 基质玻璃的声子能量降低, 上转换蓝光和红光的强度增加. 表明Tm^3＋/Yb^3＋共掺氧氯碲酸盐玻璃是一种上转换蓝光激光器的潜在基质材料.     

掺Er^3＋重金属氧氟硅酸盐玻璃的光谱性质与Judd—Ofelt理论分析

制备了掺Er^3 重金属氧氟硅酸盐玻璃，研究了玻璃的吸收光谱和荧光光谱性质，应用Judd-Ofelt理论计算了强度参数Ωt(t＝2，4，6)、Er^3 离子的振子强度、自发辐射跃迁几率、荧光分支比和辐射寿命等光谱参数。应用McCCumber理论，计算了能级^413/2→^4I15/2跃迁的受激发射截面。结果表明：掺Er^3 重金属氧氟硅酸盐玻璃具有较宽的荧光半高宽和较大的受激发射截面。对Er^3 离子在不同玻璃基质中带宽特性的比较发现，掺Er^3 重金属氧氟硅酸盐玻璃的带宽特性与碲酸盐和铋酸盐玻璃相当，大于磷酸盐、锗酸盐和硅酸盐玻璃。     

含纳米晶颗粒的Yb3+/Er3+共掺透明碲酸盐玻璃陶瓷的光谱性质研究

在组成为15Li2O-15Nb2O5-70TeO2-0.1Er2O3-0.4Yb2O3（%, 摩尔分数）的碲酸盐玻璃基础上, 采用两步热处理法制备了透明的含纳米晶颗粒碲酸盐玻璃陶瓷. 通过X射线衍射（XRD）测试表明, 玻璃陶瓷中的晶体颗粒组成为Yb6Te5O19.2或Er6Te5O19.2, 晶粒尺寸约为55 nm. 根据Judd-Ofelt理论计算了Er^3＋离子在基质玻璃和玻璃陶瓷中的光谱参数Ωt（t＝2, 4, 6）以及Er^3＋：4I15/2→4I13/2跃迁自发辐射几率, 根据McCumber理论计算了Er^3＋：4I13/2→4I15/2跃迁的发射截面. 测试了基质玻璃和玻璃陶瓷的拉曼光谱, 对比研究了铒离子在基质玻璃和玻璃陶瓷中1.5 μm处荧光和上转换光谱特性.     

Eu3+掺杂SiO2-Al2O3-B2O3玻璃制备及光谱性能研究

高温溶制了Eu^3＋掺杂SiO2-Al2O3-B2O3-MxOy（M=Li^＋,Na^＋,K^＋,Mg^2＋,Ca^2＋,Sr^2＋,RE^3＋）硼硅酸盐玻璃,测试了玻璃样品的发射光谱、激发光谱和透射光谱,研究了不同碱金属离子、碱土金属离子对该系统荧光性能的影响。利用发射光谱计算了Ω2,Ω4以及^5D0到^7F2,^7F4的自发辐射几率和振子强度f（^5D0→^7F2）,f（^5D0→^7F4）。结果表明,材料的发射能级为^5D0→^7F1（590nm）,^5D0→^7F2（617nm）,^5D0→^7F4（698nm）,而且材料的结构对称性越差,跃迁戒律打破地越彻底,荧光发射越强。     

Tm3+/Yb3+掺杂亚碲酸盐玻璃蓝红光上转换的研究

研究了掺Tm^3 /Yb^3 亚碲酸盐玻璃室温下的上转换发光。用970nm波长的半导体激光器作为泵浦源，得到了高效率的480nm波长上转换的荧光，通过对不同掺杂浓度样品的发光比较，发现了这种玻璃上转换发光的浓度猝灭现象，找出了这种玻璃得到高效率上转换发光的适宜浓度，并对Tm^3 的浓度猝灭现象进行了分析，通过对上转换发光强度与泵浦强度关系曲线的拟合，看到这种上转换是三光子吸收过程，这与通过能级图分析得到的结果相同，另外，也对650nm波长的转换发光进行了研究。     

Er3+单掺与Er3+/Yb3+双掺杂Bi2O3-GeO2-B2O3-ZnO玻璃的光谱研究

用高温融熔法制备了Er^3＋单掺与Er^3＋/Yb^3＋双掺杂的（60-x）Bi2O3-xGeO2-30B2O3-10ZnO （x=5,10, 20, 30）系统玻璃. 用差热曲线（DTA）研究了该玻璃系统的热稳定性. 结果表明, GeO2的掺入, 使得玻璃的软化温度与结晶起始温度的差增加, 玻璃的稳定性与料性增加. 测定了玻璃的吸收光谱. 应用McCumber理论计算了Er^3＋离子的受激发射截面及Er^3＋离子^4I13/2-^4I15/2发射光谱的荧光半高宽. 从吸收光谱特性出发, 应用J-O理论计算了玻璃中Er^3＋离子的强度参数（Ω2, Ω4, Ω6）, Er^3＋离子的自发跃迁几率、荧光分支比以及辐射寿命. 在970 nm波长的激发下, 研究了样品在红外波段的荧光光谱. Yb2O3的掺入, 大幅度地提高了970 nm波长的抽运效率以及在1.54 μm波段的发光强度.     

Phosphine-catalyzed annulations of azomethine imines: allene-dependent [3 + 2], [3 + 3], [4 + 3], and [3 + 2 + 3] pathways

In this paper we describe the phosphine-catalyzed [3 + 2], [3 + 3], [4 + 3], and [3 + 2 + 3] annulations of azomethine imines and allenoates. These processes mark the first use of azomethine imines in nucleophilic phosphine catalysis, producing dinitrogen-fused heterocycles, including tetrahydropyrazolo-pyrazolones, -pyridazinones, -diazepinones, and -diazocinones. Counting the two different reaction modes in the [3 + 3] cyclizations, there are five distinct reaction pathways-the choice of which depends on the structure and chemical properties of the allenoate. All reactions are operationally simple and proceed smoothly under mild reaction conditions, affording a broad range of 1,2-dinitrogen-containing heterocycles in moderate to excellent yields. A zwitterionic intermediate formed from a phosphine and two molecules of ethyl 2,3-butadienoate acted as a 1,5-dipole in the annulations of azomethine imines, leading to the [3 + 2 + 3] tetrahydropyrazolo-diazocinone products. The incorporation of two molecules of an allenoate into an eight-membered-ring product represents a new application of this versatile class of molecules in nucleophilic phosphine catalysis. The salient features of this protocol--the facile access to a diverse range of nitrogen-containing heterocycles and the simple preparation of azomethine imine substrates--suggest that it might find extensive applications in heterocycle synthesis.     

Bi3+-Er3+ and Bi3+-Yb3+ Codoped Cs2AgInCl6 Double Perovskite Near-Infrared Emitters

Bi³⁺ and lanthanide ions have been codoped in metal oxides as optical sensitizers and emitters. But such codoping is not known in typical semiconductors such as Si, GaAs, and CdSe. Metal halide perovskite with coordination number 6 provides an opportunity to codope Bi³⁺ and lanthanide ions. Codoping of Bi³⁺ and Ln³⁺ (Ln=Er and Yb) in Cs₂AgInCl₆ double perovskite is presented. Bi³⁺-Er³⁺ codoped Cs₂AgInCl₆ shows Er³⁺ f-electron emission at 1540 nm (suitable for low-loss optical communication). Bi³⁺ codoping decreases the excitation (absorption) energy, such that the samples can be excited with ca. 370 nm light. At that excitation, Bi³⁺-Er³⁺ codoped Cs₂AgInCl₆ shows ca. 45 times higher emission intensity compared to the Er³⁺ doped Cs₂AgInCl₆. Similar results are also observed in Bi³⁺-Yb³⁺ codoped sample emitting at 994 nm. A combination of temperature-dependent (5.7 K to 423 K) photoluminescence and calculations is used to understand the optical sensitization and emission processes.     

Strong visible up-conversion emission in Tb3+, Tm3+ and Tb3+-Tm3+ co-doped tellurite glasses sensitized by Yb3+

Up-conversion luminescence characteristics under 975 nm excitation have been investigated with Tb3+/Tm3+/Yb3+ triply doped tellurite glasses. Here, green (547 nm: (5)D(4)-->(7)F(4)) and red (660 nm: (5)D(4)-->(7)F(2)) up-conversion (UC) luminescence originating from Tb3+ is observed strongly, because of the quadratic dependences of emission intensities on the excitation power. Especially, the UC luminescence was intensified violently with the energy transfer from the Tm3+ ions involves in the Tb3+ excitation. To the Tb3+/Tm3+/Yb3+ triply doped glass system, a novel up-conversion mechanism is proposed as follows: the energy of (3)G(4) level (Tm3+) was transferred to (5)D(4) (Tb(3+)) and the 477-nm UC luminescence of Tm3+ was nearly quenched.     

Pseudorotational dynamics of H3+ and Li3+

The origin of the pseudoprecession phenomenon is investigated through a computational study of the time evolution of H₃⁺ and Li₃⁺ by electron nuclear dynamics theory. In particular, the pseudorotation of both molecules is shown to induce a spatial rotation, which in turn leads to Coriolis coupling of the two orthogonal nuclear shape deformation modes. This effect is rooted in an anisotropy of the molecular ground state potential energy surface that is caused by the interaction between the D_3h ground state and a twofold degenerate first excited state. Computations are performed for a variety of vibrational energies. In addition, the impact of the anharmonicity of the ground state potential surface on the shape deformation modes and the coupling between them is discussed. © 2001 John Wiley & Sons, Inc. Int J Quantum Chem, 2001     

Spectroscopic properties of Er3+, Yb3 + and Er3 + /Yb3+ doped metaphosphate glasses

The absorption and emission spectroscopies of Er3+ doped and Er3+/Yb3+ codoped Ca(PO3)2, Sr(PO3)2 and Ba(PO3)2 glasses have been studied. From the Judd-Ofelt intensity parameters, the spontaneous emission probabilities of some relevant transitions and the radiative lifetimes of several excited states of Er3+ have been calculated. The decay curves of the Er3+ emission at 1.5 microm have been measured at different temperatures. The data have been fitted using a stretched exponential function and the obtained experimental lifetimes have been compared with the calculated radiative lifetimes. The difference between the experimental and calculated lifetimes is attributed to the presence of traces of OH groups in the host glasses. The absolute OH content in some glasses has been determined from the infrared spectra. The emission spectra at 1.5 microm of the Er3+ ion in the codoped glasses have been measured at different temperatures. The integrated emission intensities decrease significantly on passing from room temperature to 13 K, suggesting a temperature dependence of the rate of the energy transfer process between Yb3+ and Er3+.     

Energy transfer between Gd3+ and Sm3+ the effect of Gd3+ on quenching of Sm3+ and intensity parameters of Sm3+ in borate glasses

Intensity parameters of Sm³⁺ in borate glasses were obtained by fitting the oscillator strengths to the Judd-Ofelt formula and a study of energy transfer from gadolinium to samarium was performed. An increase of samarium fluorescence originating from the ${}^4\text{G}{}_{\mathrm{<mtext>5</mtext><mtext>2</mtext>}}$ level was observed in the presence of gadolinium, in the concentration range of 0.1–3 wt% samarium with gadolinium constant at 3 wt%. The intensity of samarium fluorescence on excitation at 273 nm increased by one order of magnitude in the presence of gadolinium. From the excitation spectrum of the double-doped glasses (Gd + Sm), it was deduced that energy absorbed by gadolinium is transferred from ${}^6\text{P}{}_{\mathrm{<mtext>7</mtext><mtext>2</mtext>}}$ gadolinium levels to the ${}^4\text{P}{}_{\mathrm{<mtext>3</mtext><mtext>2</mtext>}}$ and ${}^4\text{P}{}_{\mathrm{<mtext>5</mtext><mtext>2</mtext>}}$ samarium levels.The mechanism of this energy transfer was obtained by plotting the energy transfer probabilities as a function of samarium concentration. A linear dependence of $\text{η}{}_0\text{η}$ (η intensity of gadolinium in the presence of samarium) versus square of concentration of Sm + Gd is obtained. From this it is concluded that the transfer is of electric-multipolar type, mainly dipole-dipole. A small increase (about 10%) of fluorescence of samarium in the presence of gadolinium excited at levels where no energy transfer can take place is attributed to the fact that the quenching of samarium occurring by the cross relaxation $\text{(}{}^4\text{G}{}_{\mathrm{<mtext>5</mtext><mtext>2</mtext>}}\text{→}{}^6\text{F}{}_{\mathrm{<mtext>9</mtext><mtext>2</mtext>}}\text{) (}{}^6\text{H}{}_{\mathrm{<mtext>5</mtext><mtext>2</mtext>}}\text{→}{}^6\text{F}{}_{\mathrm{<mtext>9</mtext><mtext>2</mtext>}}\text{)}$ is suppressed by the presence of gadolinium as seen from concentration dependence of samarium doped glasses compared to double-doped glasses.     

Er3+-Tm3+-Yb3+ tri-doped CaMoO4 upconverting phosphors in optical devices applications

The structural and optical properties of the Er³⁺-Tm³⁺-Yb³⁺codoped CaMoO₄ phosphors prepared by chemical route have been explored. The crystalline structures of the prepared phosphors have been investigated with the help of X-ray diffraction analysis. The presence of different vibrational modes and absorption bands arising due to the transitions from the ground state to different excited states of rare earth ions have been identified using the Raman and UV-VIS-NIR absorption spectra of the developed phosphor, respectively. The concentration quenching effect on the luminescence property of the prepared materials has been explained in detail. The upconversion luminescence property of the Er³⁺-Tm³⁺-Yb³⁺codoped CaMoO₄ phosphor annealed at different temperatures under 980 nm and 808 nm excitations have been reported. The energy transfer Er³⁺ → Tm³⁺, Yb³⁺ → Er³⁺ and Tm³⁺ has been found to be responsible for efficient UC emission. The dipole-dipole interaction is observed to be responsible for the concentration quenching of the luminescence intensity. The effect of annealing temperature on the upconversion luminescence property has been explained in detail. The results suggest that the developed tri-doped phosphor may be suitable in making the efficient NIR to visible upconverter and lighting based optical devices.     

沉淀法制备Sm3+,Er3+与Nd3+一次共掺杂的BaTiO3基半导体陶瓷电容器

在共沉淀法的基础上,通过双施主不同浓度的Nd3+和Sm3+,Er3+(4.0%～5.0%)掺杂,研究了BaTiO3基表面型陶瓷电容器的电性能,结果表明,Sm3+和Er3+的掺杂可以提高居里温度,但使介电常数降低,其含量为25%时可获得绝缘电阻500 MΩ左右,C/S为0.5895μf·cm-2电性能参数.     

Tb~(3+)在YAG中的发光及Tb~(3+)与Tm~(3 +)间的能量传递

采用溶胶 -凝胶方法合成了系列化合物 (Y1 -x- yTbxTmy) 3Al5O1 2 ,研究了Tb3+在该化合物中的发光及其浓度对发光性质的影响 ,以及Tb3+与Tm3+间的能量传递现象。