KZnF3中Ce^3＋→Eu^2＋的能量传递

研究了ＫＺｎＦ３中Ｃｅ＾２＋和Ｅｕ＾２＋的光谱特性,在共掺Ｃｅ＾３＋和Ｅｕ＾２＋的体系中,观察到了Ｃｅ＾３＋对Ｅｕ＾２＋的能量传递过程,计算了能量传递的量子效率,探讨了能量传递机理,研究发现,Ｃｅ＾３＋的存在有利于Ｅｕ＾２＋的ｆ－ｆ跃迁线状发射。     

Ce^3＋和Eu^2＋共激活氯硅酸锌钙的光谱和敏化特性

合成了Ｃｅ＾３＋和Ｅｕ＾２＋共激活的氯硅酸锌钙「Ｃａ８Ｚｎ（ＳｉＯ４）４Ｃｌ２：Ｃｅ＾３＋，Ｅｕ＾２＋」绿色荧光粉，并报道了它们的漫反射光谱，激光发光谱及发射光谱，观测到氯硅酸锌钙中Ｃｅ＾３＋对Ｅｕ＾２＋离子发光的显著敏化现象。阐述了氯硅酸锌钙中Ｃｅ＾３＋和Ｅｕ＾２＋发光作用缘于Ｃｅ＾３＋和Ｅｕ＾２＋之间的高效无辐一传递。     

Ce3+和Tb3+掺杂的稀土硼酸盐玻璃的发光性质

报道Ｃｅ＾３＋和Ｔｂ＾３＋掺杂的硼酸盐玻璃的合成及该系列玻璃的激发和发射光谱性质。在紫外光激发下,玻璃中的Ｃｅ＾３＋发射蓝紫光,Ｔｂ＾３＋发射有特征的绿光,在Ｃｅ＾３＋和Ｔｂ＾３＋共掺杂的体系中,可观察到Ｃｅ＾３＋强烈敏化Ｔｂ＾３＋发光的现象。分析表明,Ｃｅ＾３＋和Ｔｂ＾３＋之间存在辐射能量传递稿铲无辐射能量传递。     

氟化镁锶中铕和铽的电荷迁移及其平衡解析

在氩气氛中，合成子ＳｒＭｇＦ４：ｘＥｕ，ｙＴｂ复合氟化物磷光体，该体系中Ｅｕ＾３＋和Ｅｕ＾２＋共存，随共掺入Ｔｂ浓度的增加，Ｅｕ＾３＋的荧光发射强度降低，Ｅｕ＾３＋的发光增强，并且Ｅｕ＾２＋的ＥＳＲ信号增强，认为Ｅｕ＾３＋和Ｔｂ３＋之间存在的电荷迁移，即Ｅｕ＾３＋Ｔｂ＾３＋→Ｅｕ＾２＋＋Ｔｂ＾４＋，通过半量手段研究了这一电荷迁移反应的平衡常数。     

GdxY1—XP5O14：Ce,Tb的发光和能量传递：Ⅰ.制备,结构和光谱性质

研究了稀土五磷酸盐Ｇｄｘ１－ＸＰ５Ｏ１４：Ｃｅ，Ｔｂ体系的制备，结构和光谱性质。当ｘ＞０．７时，该材料属单斜晶系Ｉ，Ｐ２１／ｃ结构，当≤０．７时，属单斜晶系Ⅱ，Ｃ２／ｃ结构。研究了ＧｄＰ５Ｏ１４：Ｃｅ，Ｔｂ６ ＹＰ５Ｏ１４：Ｃｅ，Ｔｂ的荧光光谱，确定了通过基质Ｇｄ离子中介的Ｃｅ＾３＋→Ｇｄ＾３＋→Ｔｂ＾３＋能量传递的现象。     

Eu^3＋,Bi^3＋Me2Y8（SiO4）6O2中的发光特性与取代格位

在紫外光激发下，Ｅｕ＾３＋和Ｂｉ＾３＋在Ｍｅ２Ｙ８（ＳｉＯ４）６Ｏ２基质（Ｍｅ＝Ｍｇ，Ｚｎ，Ｃａ，Ｓｒ）中分别发射红光（＾５Ｄ０－＾７Ｆ２）和蓝光（＾３Ｐ１－＾１Ｓ０）．Ｅｕ＾３＋发光的红橙比随着激发波长和Ｍｅ＾２＋的不同而变化。荧光拉曼光谱表明，Ｅｕ＾３＋在四种基质中同时占据了４ｆ格位和６ｈ格位。依据Ｂｉ＾３＋发光的Ｓｔｏｋｅｓ位移推断，当Ｍｅ＝Ｃａ，Ｚｎ时，Ｂｉ＾３＋主要占据４ｆ格位，而当Ｍｅ     

吡嗪—2,3—二羧酸体系导数荧光法同时测定铕,铽

研究了以吡嗪－２，３－二羧酸为荧光试剂应用导数荧光技术同时测定Ｅｕ＾３＋，Ｔｂ＾３＋的最佳条件，共存离子的影响和Ｅｕ＾３＋，Ｔｂ＾３＋－ＰＹＤＡ配合物的配合比，稳定常数及光机理，Ｅｕ＾３＋，Ｔｂ＾３＋的检测限分别达４．０和２．０ｎｇ／ｍＬ，利用本方法成功地测定了稀土试样中铕、铽的含量。     

稀土离子与牛血Cu（Zn）—SOD的作用

采用ＥＳＲ、ＣＤ谱和荧光光谱研究了ｐＨ＝６．３时六次甲基四胺－ＨＣｌ缓冲溶液中ＬａＣｌ３和ＴｂＣｌ３与Ｃｕ（Ｚｎ）－ＳＯＤ的配位作用和结构。Ｃｕ（Ｚｎ）－ＳＯＤ可增强Ｔｂ＾３＋的荧光发射，Ｔｂ＾３＋与Ｃｕ（Ｚｎ）－ＳＯＤ有多个配位位置，其中有２个强结合位点，Ｌａ＾３＋可Ｔｂ＾３＋可竞争Ｃｕ（Ｚｎ）…ＳＯＤ上相同结合位点，７７Ｋ下Ｌａ＾３＋与Ｔｂ＾３＋使Ｃｕ（Ｚｎ）－ＳＯＤ的Ｃｕ＾２＋活性中心的配位     

稀土离子对DNA作用的循环伏安法和光谱法研究

运用循环伏安法，紫外光谱和拉曼光谱等方法研究了Ｅｕ＾３＋，Ｃｅ＾３＋，Ｅｒ＾３＋，Ｓｍ＾３＋，Ｔｂ＾３＋，Ｌａ＾３＋，Ｎｄ＾３＋等稀土金属离子与ＤＮＡ（小牛胸腺）的相互作用，Ｃｅ＾３＋与ＤＮＡ作用后，Ｃｅ＾３＋的ＣＶ曲线的峰电流密度明显降低，且氧化峰降低的程度大于还原峰，Ｃｅ＾３＋的差示ＵＶ曲线呈减色效应，且在２７２ｎｍ处出现新峰，ＤＮＡ的差示ＵＶ曲线呈增色效应；ＤＮＡ的拉曼谱线中８１４ｃｍ＾－１     

Eu^2＋在BaF2—xYF3体系中的光谱性质及其对Tb3＋的能量传递

研究了钡钇复合氟化物体系中Ｅｕ＾２＋的光谱性质和变化规律，讨论了影响Ｅｕ＾２＋光谱的因素，特别是氧的存在对Ｅｕ＾２＋激发和发射能量的影响，发现在ＢａＹＦ５基质中Ｅｕ＾２＋对Ｔｂ＾３＋的有效参量传递。     

On Theoretical Treatments of Electronic Excitation Energy Transfer

In this paper, we review the generalized Forster-Dexter theory to treat photoinduced electronic energy transfer for a system in dense media and for an isolated system (i.e., a system in the collision-free condition). Instead of expressing the rate of energy transfer in terms of spectral overlap, the expression of the energy-transfer rate constant is obtained by evaluating a Fourier integral involved in the energy transfer rate constant using the saddle-point method. In this way, the energy-gap dependence, and the effect of temperature and the isotope effect on the energy transfer can be easily studied. The effect of bridge groups connecting between donor and acceptor chromophores on the intramolecular energy transfer is also studied.     

化工传递过程中的类似性

通过分析化工过程中的传递现象 ,总结了动量传递、热量传递和质量传递过程的一些类似性 ,并且讨论了这些类似性的理论和应用价值。     

有机半导体材料中的电荷转移

在介绍有机半导体材料电荷转移基本理论的基础上,对利用电荷转移研究有机半导体材料的导电、光电导和发光过程的现状进行评述,认为电荷转移是有机半导体材料研究的关键问题,开展其研究不仅有助于弄清一些新现象、新效应的物理起因,还可望找到预测有机半导体材料相关性能的有效手段.     

Theoretical study of electron transfer in uranyl(VI)–uranyl(V) complexes in solution

The rates of the electron self‐exchange between uranyl(VI) and uranyl(V) complexes in solution have been investigated in detail with quantum chemical methods. The calculations have shown that the bond length of U? Oyl is elongated by 0.1 Å when the extra electron is localized on the sites. The diabatic potential surfaces are obtained. The inner reorganization energies are 212.6 and 226.8 kJ mol^?1 for hydroxide and fluoride bridge systems, respectively. The solvent reorganization energies are 28.12 and 31.60 kJ mol^?1 for hydroxide and fluoride bridge systems, respectively. The nuclear frequency factors are 3.17 × 10¹³ and 3.12 × 10¹³ s^?1 for hydroxide and fluoride bridge systems, respectively. The electronic coupling matrix elements are 1.89 and 4.06 kJ mol^?1 for hydroxide and fluoride bridge systems, respectively. The electron‐transfer rates of our calculations are 12.95 and 0.819 M^?1 s^?1 for hydroxide and fluoride bridge systems, respectively. © 2009 Wiley Periodicals, Inc. Int J Quantum Chem, 2010     

A simplified approach for the coupling of excitation energy transfer

A simplified approach for computing the electronic coupling of nonradiative excitation-energy transfer is proposed by following Scholes et al.’s construction on the initial and final states [G.D. Scholes, R.D. Harcourt, K.P. Ghiggino, J. Chem. Phys. 102 (1995) 9574]. The simplification is realized through defining a set of orthogonalized localized MOs, which include the polarization effect of the charge densities. The method allows calculating the coupling of both the singlet-to-singlet and triplet-to-triplet energy transfer. Numerical tests are performed for a few of dimers with different intermolecular orientations, and the results demonstrate that Coulomb term are the major contribution to the coupling of singlet-to-singlet energy transfer whereas in the case of triplet-to-triplet energy transfer, the dominant effect is arisen from the intermolecular charge-transfer states. The present application is on the Hartree-Fock level. However, the correlated wavefunctions which are normally expanded in terms of the determinant wavefunctions can be employed in the similar way.     

化工原理教学中传质对传热教学的启发及运用

The common points of absorption and heat transfer were found by comparison of the assumptions and transfer model. Furthermore, the computational formula and graphs of the number and the length of a transfer unit were deduced in the countercurrent heat transfer through learning from the treatment method of absorption. Based on the study, the basic analysis methodology for qualitative analysis of operational heat transfer problems was proposed. The connection between mass transfer and heat transfer was established through the comparison, so that they were no longer random knowledge points, which was beneficial for students to understand and master principles of chemical engineering.     

Photoinduced intermolecular and intramolecular actions between eosin and porphyrin

Two dyads of eosin and porphyrin linked with a semi-rigid (-CH2phCH2-) or flexible (-(CH2)4-) bridge and their reference model compounds were synthesized and characterized The intermoleccular interaction and intramolecular photoinduced singlet energy transfer and electron transfer were studied by their absorp tion spectra,fluorescence emission,excitation spectra and fluorescence lifetime The model compounds,ethyl ester of eosm (EoEt) and porphyrin (PorEt),could form complexes in the ground state.When the eosin moieties in dyads were excited,they could transfer some singlet energy to the porphyrins; in the meantime,they could also ndsce electron transfer between two chromophores.Exciting the porphyrin moieties in dyads could induce electron transfer from eosin moieties to porphyrin moieties.The efficiencies (EnT,ET) and rate constants (kEnT,kET) were related to the polarity of solvents and mutual orientation of the two chromophores in dyads.     

Electron Transfer and Charge Transfer: Twin Themes in Unifying the Mechanisms of Organic and Organometallic Reactions

The broad varieties of organic and organometallic reactions merge into a common unifying mechanism by considering all nucleophiles and electrophiles as electron donors (D) and electron acceptors (A), respectively. Comparison of outer-sphere and inner-sphere electron transfers with the aid of Marcus theory provides the thermochemical basis for the generalized free energy relationship for electron transfer (FERET) in Equation (37) and its corollaries in Equations (43) and (44) that have wide predictive applicability to electrophilic aromatic substitutions, olefin additions, organometallic cleavages, etc. The FERET is based on the conversion of the weak nucleophile–electrophile interactions extant in the ubiquitous electron donor—acceptor (EDA) precursor complex [D, A] to the radical ion pair [D^⊕, A^?], for which the free energy change can be evaluated from the charge-transfer absorption spectra according to Mulliken theory. FERET analysis thus indicates that the charge-transfer ion pairs [D^⊕, A^?] are energetically equivalent to the transition states for nucleophile/electrophile transformations. The behavior of such ion pairs can be directly observed immediately following the irradiation of the charge-transfer bands of various EDA complexes with a 25-ps laser pulse. Such studies confirm the radical ion pair [Arene^⊕, NO₂] as a viable intermediate in electrophilic aromatic nitration, as presented in the electron-transfer mechanism between arenes and the nitryl cation (NO) electrophile.     

Theoretical studies of electron and hydrogen transfer reactions between semiquinone radicals and oxygen

 To explore the interactions between ubiquinones and oxygen in living organisms, the thermodynamics of a series of electron and hydrogen transfer reactions between semiquinone radicals, as well as their corresponding protonated forms, and oxygen, singlet or triplet, were studied using the hybrid Hartree–Fock–density functional theory method Becke's three parameter hybrid method with the Lee, Yang, and Parr correlation functional. Effects of the solvent and of the isoprenyl tail on the electron and hydrogen transfer reactions were also investigated. It is found that semiquinone radicals (semiquinone anion radicals or protonated semiquinone radicals) cannot react with triplet oxygen to form the superoxide anion radical O₂ ⁻. In contrast, neutral quinones can scavenge O₂ ⁻ efficiently. In the gas phase, only protonated semiquinone radicals can react spontaneously with singlet oxygen to produce peroxyl radical (HO₂). However, both semiquinone anion radicals and protonated semiquinone radicals can react with singlet oxygen to produce harmful oxygen radicals (O₂ ^{− a l l b u l l} and HO₂, respectively) in aqueous and protein environments. The free-energy changes of the corresponding reactions obtained for different ubiquinone systems are very similar. It clearly shows that the isoprenyl tail does not influence the electron and hydrogen transfer reactions between semiquinone radicals and oxygen significantly. Results of electron affinities, vertical ionization potentials, and proton affinities also show that the isoprenyl tail has no substantial effect on the electronic properties of ubiquinones. Received: 3 July 2000 / Accepted: 6 September 2000 / Published online: 21 December 2000