稀土配合物的时间分辨荧光光谱法研究(Ⅱ)——Eu,Sm-DBM-TOPO体系的荧光衰减动力学特性和激光诱导时间分辨荧光光谱

本文以Nd:YAG泵浦的染料激光器为激发光源,门控光学多道分析仪为检测器,自制的触发器和荧光盒组装成一台激光诱导时间分辨光谱装置。采用此装置研究了在表面活性剂Triton X-100存在下铕、钐-二苯甲酰甲烷-三正辛基氧化膦(Eu、Sm-DBM-TOPO)体系的激光诱导发光光谱特性和荧光衰减动力学特性。讨论了荧光发射过程中的能量传递机制。拟定出测定痕有铕和钐的时间分辨光谱方法,用于高纯稀土氧化物等样品中痕量铕和钐的测定,结果满意。     

时间分辨偏振红外光谱及其应用

时间分辨偏振红外光谱已被广泛应用于研究光化学过程中的分子结构动力学. 通过测定瞬态物质跃迁偶极矩之间的角度等结构信息,可以提供光化学过程中伴随的电荷分布、分子结构和构象变化等动态信息. 包括简要介绍时间分辨偏振红外光谱技术的原理和应用：(i) 时间分辨偏振红外光谱概述;(ii) 时间分辨偏振红外光谱的原理及其优势;(iii) 利用时间分辨偏振红外光谱探测多种化学动力学过程,例如蛋白质构象动力学、激发态的电子局域化和光致异构化等;(iv) 时间分辨偏振红外光谱的局限和发展前景.     

水溶性CdTe量子点的稳态和纳秒时间分辨光致发光光谱

报道了以飞秒脉冲激光为激发光源的水溶性CdTe量子点(QDs)的稳态荧光光谱和纳秒时间分辨荧光光谱.实验发现CdTe量子点的荧光光谱峰值位置随激发波长变化发生明显移动，激发脉冲波长越长，荧光峰位红移越大.荧光动力学实验数据显示，在400nm和800nm脉冲激光激发下，水溶性CdTe量子点的荧光光谱中均含有激子态和诱捕态两个衰减成分，两者的发射峰相距很近，诱捕态的发射峰波长较长.在800nm脉冲激光激发下的诱捕态成分占总荧光强度的比重比400nm激发下的约高3倍，其相对强度的这种变化导致了稳态荧光发射峰位的红移. 关键词： CdTe 量子点 时间分辨 荧光光谱 上转换荧光     

低温基体隔离SO2a^～3B1态的时间分辨磷光光谱研究

采用脉冲紫外激光作激发光源，用时间分辨技术测定了ＳＯ２分子在低温Ａｒ，Ｎ２，ＣＯ基体离条件下的激光诱导发光光谱。研究结果表明，在低温基体隔离条件下，ＳＯ２激发至单重态后主要通过系间交叉跃迁ㄎ成ａ＾～３Ｂ１态，ａ＾～３Ｂ１态的生长时间约为２－３μｓ。从三态磷光光谱的谱带加宽和红称可以看出ＳＯ２和三种基体之间的相互作用大小为：ＣＯ基体＞Ｎ２基体＞Ａｒ基体；另外，从ＳＯ２系间交叉跃迁效率可以看出，在３５     

同步辐射X射线荧光光谱国内外研究进展

同步辐射光源是带电粒子在加速器储存环中以接近光速的速度运动时,沿轨道切线方向发射出的辐射,同步辐射X射线荧光分析(SR-XRF)是以同步辐射X射线作为激发光源的X荧光光谱分析技术.同步辐射X射线荧光分析包括了用于微区及微量元素分析的同步辐射XRF、用于表面及薄膜分析的同步辐射全反射X射线荧光(SR-TXRF)以及用于三...     

多环芳烃时间分辨荧光光谱特性研究

利用时间分辨荧光光谱技术,研究了菲、荧蒽、芴、蒽、芘等五种多环芳烃的荧光时间分辨发射光谱特性。以289 nm受激拉曼光作为激发光源,研究了289 nm激发光作用下五种多环芳烃的延时特性和门宽特性。并以多环芳烃随延时时间的荧光峰强度衰减关系曲线,得到菲、荧蒽、芴、芘的荧光寿命分别为37.0, 32.7, 10.9, 147.0 ns。不同荧光物质具有特定的荧光光谱特性,多环芳烃时间分辨荧光光谱特性的研究可以为复杂水体中不同种类多环芳烃的诊断提供依据。     

磷光染料掺杂有机分子发光的能量转移研究

用稳态光谱和时间分辨的超快光谱研究了不同浓度磷光染料PtOEP掺杂有机小分子Alq薄膜的发光特性和能量转移.据PtOEP的吸收光谱与Alq的荧光光谱,用Frster理论估算出Alq:PtOEP掺杂体系的能量转移临界半径及其转移效率.稳态荧光光谱显示,在Alq:PtOEP掺杂薄膜中,随着掺杂浓度的升高,PtOEP的发光强度增强,Alq的发光强度逐渐减弱,两者间的能量转移效率与理论计算结果一致.利用时间分辨光谱研究了Alq:PtOEP掺杂薄膜体系的能量转移动力学过程,观察到Alq:PtOEP掺杂薄膜的荧光寿 关键词： 有机掺杂薄膜 稳态光谱 时间分辨光谱 能量转移     

Eu（Sm）—DBM—CPB体系的激光感生时间分辨荧光光谱的研究

用自装的激光感生时间分辨荧光光谱装置，研究了Ｅｕ，Ｓｍ－二苯甲酰甲烷（ＤＢＭ）体系在阳离子表面活性剂溴代十六烷基吡啶（ＣＰＢ）存在下的光谱特性和荧光衰减动力学特性。给出同时测定Ｅｕ和Ｓｍ的激光感生时间分辨荧光光谱分析方法，用于高纯氧化物中痕量Ｅｕ和Ｓｍ的测定，获得了满意的结果。     

人血单个红细胞的共振拉曼光谱研究

给出了人血单个红细胞在不同激发光源下的共振拉曼光谱。从实验谱中得到 ,构象不灵敏的苯丙氨酸的单取代基环的伸缩振动谱线 10 0 2cm-1和吡咯环的CN呼吸振动谱带中 16 2 0cm-1的谱线 ,对 782nm激发光源共振较强 ,呈现出强度大而半高宽小的尖锐谱线 ;而在 5 14nm激发光源下 ,该两条谱线较弱。其他谱线 ,高波数段 (大于 135 0cm-1) ,在 5 14nm激发光源下 ,谱线强度大且清晰 ;低波数段 (小于 135 0cm-1) ,对应 782nm激发光源的拉曼谱线强而明显。同时还给出了同一激光光源下 ,取血后不同时间单个红细胞的拉曼光谱。发现对 782nm激发光源 ,除 16 0 1cm-1谱线强度减小外 ,其他无明显变化 ;而对 5 14nm激发光源 :一是有许多条谱线强度减小 ,二是许多条谱线向低波数移动了 4～ 10cm-1波数左右。这些实验结果 ,可以为研究单个红细胞的结构、功能及进一步研究病变细胞的变异提供有力的实验基础。     

LDS751染料分子的时间分辨荧光谱

本文介绍用飞秒时间分辨荧光凹陷探测技术,获得激发态分子时间分辨荧光光谱的方法。文中描述了实验方法及其特点,给出了ＬＤＳ７５１染料分子的飞秒时间分辨荧光光谱。     

Electronic properties of hydrogen storage materials with photon-in/photon-out soft-X-ray spectroscopy

The applications of resonant soft X-ray emission spectroscopy on a variety of carbon systems have yielded characteristic fingerprints. With high-resolution monochromatized synchrotron radiation excitation, resonant inelastic X-ray scattering has emerged as a new source of information about electronic structure and excitation dynamics. Photon-in/photon-out soft-X-ray spectroscopy is used to study the electronic properties of fundamental materials, nanostructure, and complex hydrides and will offer potential in-depth understanding of chemisorption and/or physisorption mechanisms of hydrogen adsorption/desorption capacity and kinetics.     

Photoelectron spectroscopy in the energy region 30 to 800 eV using synchrotron radiation

With the advent of synchrotron radiation, the photoemission techniques were extended to a continuous range of excitation energies in the far ultraviolet and soft x-ray regions, adding tremendously to the usefulness of photoemission as a probe of the electronic structure of materials. In this paper, we discuss the application of photoelectron spectroscopy using synchrotron radiation to the studies of oxygen chemisorption/oxidation of Si surfaces, metal overlayers on III-V semiconductor surfaces, chemisorption on transition metal surfaces, and the surface electronic structure of CuNi alloys.     

Heterodyne detection of synchrotron radiation

A time integral method for the study of resonant nuclear scattering of synchrotron radiation in the forward direction is presented. The method relies on the interference of radiation scattered by nuclei in two samples, one moving with respect to the other. The method, termed heterodyne detection of synchrotron radiation, gives the same information on hyperfine parameters as the well known differential method. The general formalism is developed for the case where the reference is a single line sample and the investigated sample has magnetic or quadrupole splitting. The first experiments are discussed. A comparison of time differential synchrotron radiation spectroscopy, heterodyne detection and Mössbauer spectroscopy is given.     

Luminescence and ESR characteristics of γ-irradiated Lu3Al5O12:Ce single crystalline film scintillators

The influence of γ-irradiation with a dose of ～10⁴ Gy on the characteristics of LuAG:Ce single crystalline films (SCF) was investigated using ESR and time-resolved luminescence spectroscopy under excitation by synchrotron radiation with the energies ranging from 3.7 to 12 eV. The origin of γ-ray induced radiation defects in LuAG:Ce SCF is discussed.     

Total reflection x‐ray fluorescence analysis—a review

Total reflection x‐ray fluorescence analysis (TXRF) is a special energy‐dispersive x‐ray analytical technique extending XRF down to the ultra trace element range. Detection limits of picograms or nanograms per gram levels are reached with x‐ray tube excitation. Using synchrotron radiation as excitation source, femtogram levels are detectable, particularly important for Si wafer surface analysis. TXRF is specially suited for applications in which only a very small amount of sample is available, as only a few micrograms are required for the analysis. In this review, an overview of theoretical principles, advantages, instrumentation, quantification and application is given. Chemical analysis as well as surface analysis including depth profiling and thin‐film characterization is described. Special research results on extension to low‐Z elements, excitation with synchrotron radiation and x‐ray absorption spectroscopy (XAS) for chemical speciation at trace levels are reviewed. Copyright © 2007 John Wiley & Sons, Ltd.     

High-pressure Mössbauer spectroscopy with nuclear forward scattering of synchrotron radiation

Abstract

Using a diamond anvil cell, high-pressure ⁵⁷Fe Mössbauer spectroscopy has been performed with the nuclear forward scattering of synchrotron radiation. A pressure-induced magnetic hyperfine interaction at ⁵⁷Fe in SrFeO_{2, 97} has been detected at 44 GPa and 300 K for a first time by a quantum-beat modulation of the decay rate after collective nuclear excitation by the synchrotron pulse. The basic concept and method used to detect nuclear forward scattering with synchrotron radiation are discussed.     

Recoil effect of photoelectrons in the Fermi edge of simple metals

High energy resolution photoelectron spectroscopy of conduction electrons in the vicinity of the Fermi edge in Al and Au at excitation energies of 880 and 7940 eV was carried out using synchrotron radiation. For the excitation energy of 7940 eV, the observed Fermi energy of Al shows a remarkable shift to higher binding energy as compared with that of Au, with accompanying broadening. This is due to the recoil effect of the emitted photoelectrons. The observed spectra are well reproduced by a simple model of Bloch electrons based on the isotropic Debye model.     

Interconfigurational 5d?→?4f luminescence of Ce(3+) and Pr(3+) in Ca(9)Lu(PO(4))(7)

Ca(9)Lu(PO(4))(7):Ce (3+) and Ca (9)Lu (PO (4))(7):Pr (3+) polycrystalline materials were synthesized by solid state reaction at high temperature. The materials were characterized by powder x-ray diffraction (XRPD). The luminescence spectroscopy and the excited state dynamics of these compounds were investigated upon excitation with UV/VUV synchrotron radiation. Both materials showed efficient and fast 5d-4f emission upon direct VUV excitation into the 5d levels but only Ca(9)Lu(PO(4))(7):Ce (3+) revealed luminescence upon excitation across the bandgap. The decay kinetics of the 5d-4f emission upon VUV intra-center excitation is characterized by a decay time of 29?ns for Ce (3+) and 17 ns for Pr (3+) with no significant build-up after the excitation pulse. For the both compounds, no significant temperature dependence of the 5d-4f emission lifetime was observed within the range 8-300?K.     

Luminescence and electronic excitations in KBe<Subscript>2</Subscript>BO<Subscript>3</Subscript>F<Subscript>2</Subscript> crystals

This paper reports on a study of the dynamics of electronic excitations in KBe₂BO₃F₂ (KBBF) crystals by low-temperature luminescent vacuum ultraviolet spectroscopy with nanosecond time resolution under photoexcitation by synchrotron radiation. The first data have been obtained on the kinetics of photoluminescence (PL) decay, time-resolved PL spectra, time-resolved PL excitation spectra, and reflection spectra at 7 K; the estimation has been performed for the band gap E _g = 10.6−11.0 eV; the predominantly excitonic mechanism for PL excitation at 3.88 eV has been identified; and defect luminescence bands at 3.03 and 4.30 eV have been revealed. The channels of generation and decay of electronic excitations in KBBF crystals have been discussed.     

Low-temperature time-resolved vacuum ultraviolet spectroscopy of self-trapped excitons in KH<Subscript>2</Subscript> PO<Subscript>4</Subscript> crystals

A complex investigation of the dynamics of electronic excitations in potassium dihydrophosphate (KDP) crystals is performed by low-temperature time-resolved vacuum ultraviolet optical luminescence spectroscopy with subnanosecond time resolution and with selective photoexcitation by synchrotron radiation. For KDP crystals, data on the kinetics of the photoluminescence (PL) decay, time-resolved PL spectra (2–6.2 eV), and time-resolved excitation PL spectra (4–24 eV) at 10 K were obtained for the first time. The intrinsic character of the PL of KDP in the vicinity of 5.2 eV, which is caused by the radiative annihilation of self-trapped excitons (STEs), is ascertained; σ and π bands in the luminescence spectra of the STEs, which are due to singlet and triplet radiative transitions, are resolved; and the shift of the σ band with respect to the π band in the spectra of the STEs is explained.