不同波长激光辐照对痢疾杆菌生物学效应的影响

分别采用功率密度为1.7W/cm²、照射剂量为2000J/cm²的Ar⁺激光与LD激光辐照高耐药性的志贺氏福氏痢疾杆菌,波长较短的Ar⁺激光(488nm)所引起细菌的致死率与药敏实变率明显高于波长较长的LD激光(808nm),即波长较短的Ar⁺激光的辐照导致细菌耐药性显著降低.     

Laser-induced Alignment and Coulomb Explosion of CO2

实验研究了CO₂分子在飞秒强激光脉冲作用下的动力学过程,包括分子取向,隧穿电离和库仑爆炸,激光强度从1×10¹³W/cm²变化到6×10¹⁴W/cm². 当激光强度小于分子的电离阈值时,CO₂分子的非绝热转动激发形成一个相干转动波包,波包演化导致分子沿激光电场方向取向. 激光脉冲结束后,分子取向可以周期性地再现,利用另一束激光可以对取向结构进一步进行修饰. 当激光强度大于分子     

激光功率密度对Al膜靶后表面快电子发射的影响

 报道了在20 TW皮秒激光器上完成的p偏振激光与等离子体相互作用过程中产生的快电子的角分布和能谱测量结果。实验得到：当激光功率密度小于10¹⁷ W/cm²时,电子发射没有明显定向性,在激光入射面内多峰发射;当激光功率密度大于10¹⁷ W/cm2,小于10¹⁸ W/cm²时,电子主要沿靶面法线方向发射;当激光功率密度达到相对论强度时,电子主要沿激光传播方向发射;激光功率密度未达到相对论强度时,靶后表面法线方向快电子能谱拟合平均温度符合共振吸收温度定标率;激光功率密度达相对论强度以上时,靶后表面法线方向快电子能谱拟合平均温度高于已有的温度定标率。     

纳秒激光电离分子团簇产生高离化离子的激光波长效应

 利用脉冲分子束-激光电离-飞行时间质谱仪，在10⁹～10¹² W·cm^-2激光功率密度条件下，考察了Nd：YAG激光器输出的1 064，532，266 nm波长的激光与苯、氨、硫化氢等团簇的相互作用。发现1 064 nm的激光可以电离分子束产生高离化态的C⁴⁺，N⁵⁺，S⁶⁺等离子；波长为532 nm的激光则电离产生价态较低的C³⁺，C²⁺，N³⁺，N²⁺， S⁴⁺，S³⁺以及S²⁺ 等离子；在266 nm波长条件下进行实验，没有产生任何高价离子。提出了一个“多光子电离引发-逆轫致吸收加热-电子碰撞电离”模型来解释高价离子的产生。激光场下电子在团簇内部的逆轫致加热是整个过程的关键步骤，电子被加热的速度正比于激光波长的平方。这可以解释为何长波长的激光有利于更高价态离子的产生。     

激光离子源的首次在线实验结果

介绍了在线同位素分离器使用激光离子源的重要性、激光离子源原理和相关激光技术,以及热毛细管激光离子源和靶室的结构.在首次在线实验中使用50MeV/u ¹⁸O+^natTa→¹⁶⁷Yb(T_1/2=17.5m)反应道,实现了加速器、分离器和激光系统的联合运行.通过测量分离后产物的γ谱,确定了分离后的¹⁶⁷Yb的产额,并与从产生截面、束流强度、收集时间和靶厚度计算得到的产生率相比,得到总分离效率约为0.2%.通过有激光与无激光条件下测量的γ谱中¹⁶⁷Yb与¹⁶⁷Lu相应峰下面积比值K得到元素选择性η为3.2.发现了新的¹⁶⁷Yb的长寿命高自旋的同质异能态,分析了提高效率的途径.     

飞秒激光-薄膜靶相互作用中超热电子产额和激光转化效率

 在激光能量130 mJ（靶面），脉宽60 fs，波长800 nm，对比度1∶10^-6，激光与靶法线成45°夹角，P偏振，靶面激光峰值功率密度约为7.0×10¹⁷ W·cm^-2，无预脉冲的条件下，采用电子谱仪与经γ标准源标定的LiF热释光探测器（TLD）相配合，测量了飞秒激光-薄膜靶相互作用中产生的超热电子能谱。根据所测的能谱，推算出超热电子的产额和激光能量转化为超热电子能量的效率，在靶法线方向分别为1.19×10¹⁰/sr和4.55%/sr，在激光反射方向分别为1.83×10⁹/sr和0.76%/sr。结果显示，不同方向的超热电子产额和激光转化效率有所不同，原因在于激光-等离子体相互作用产生的超热电子构成各向异性的分布。     

机载激光测深回波信号的处理和研究

对激光海洋测深信号特性进行了分析,采用变增益法预处理机载激光测深回波信号,可以压缩水面激光反射信号的光通量与水底目标返回信号光通量的动态范围,实验结果使其动态压缩范围达10³～10⁴量级,满足机载蓝绿激光测深的要求。     

488 nm连续激光晶化本征非晶硅薄膜的喇曼光谱研究

利用等离子增强化学气相沉积系统制备了本征非晶硅薄膜,并选用488 nm波长的连续激光进行晶化.采用喇曼测试技术对本征非晶硅薄膜在不同激光功率密度和扫描时间下的晶化状态进行了表征,并用514 nm波长与488 nm波长对样品的晶化效果进行了比较.测试结果显示:激光照射时间60 s, 激光功率密度在1.57×10⁵ W/cm²时,能实现非晶硅向多晶硅的转变,在功率密度达到2.7 56×10⁵ W/cm²时,有非晶开始向单晶转变,随着激光功率密度的继续增加,晶化结果仍为单晶;在功率密度为2.362×10⁵ W/cm²下,60 s照射时间晶化效果较好;在功率密度为2.756×10⁵ W/cm²和照射时间为60 s的条件下,用488 nm波长比514 nm波长的激光晶化本征非晶硅薄膜效果较好,并均为单晶态.     

低强度激光泵浦类Ni离子X光激光实验

 在试运行的神光Ⅱ装置上,采用新设计的凸柱面透镜列阵均匀线聚焦系统, 用两束激光焦线叠加和双靶对接等技术,以预主脉冲激光驱动方式,在(5～8)×10¹³W/cm²的较低强度激光泵浦条件下,观测到Ni-like　Dy、Er、Yb的软X光激光输出,测得波长5.02nm类Ni-Yb和波长5.86nm类Ni-Dy的软X光激光的增益系数分别为1.6cm^-1和1.4cm^-1     

等离子体屏蔽和稀疏波对冲量耦合系数的影响

 利用脉冲Nd:YAG激光作用在铝、铜靶上，研究了不同入射激光能量下冲量耦合系数和离焦量之间的关系，以及不同功率密度情况下冲量耦合系数和光斑直径的关系。实验表明铝靶在入射激光脉冲能量由75.8 mJ增加到382.3 mJ时，冲量耦合系数峰值对应的最佳离焦量由－10 mm处远离焦点向透镜方向移到－18 mm，而对应的激光功率密度仅由2.0×10⁹ W/cm²增加到3.9×10⁹ W/cm²；铜靶实验规律和铝靶类似。等离子体屏蔽的吸收作用导致了冲量耦合系数达到最大值后迅速降低。铝靶在入射激光功率密度由0.7×10⁹ W/cm²增大到1.0×10¹⁰W/cm²时，冲量耦合系数随光斑直径增大而增大，对应变化斜率由5.2×10^-5N·s/（mm·J）增大到49.2×10^-5N·s/（mm·J），表明了稀疏波对冲量耦合系数的削弱作用随入射激光功率密度增加而增加，随光斑直径增大而减小。     

共振光散射技术测定核酸的研究进展

核酸分析是生命科学研究中最重要的技术之一。目前主要是应用核酸内源紫外吸收光谱的紫外分光光度法和基于荧光探针分子与核酸相互作用的荧光分光光度法。紫外分光光度法灵敏度低 ,荧光分光光度法试剂昂贵 ,有毒性。近年来 ,共振光散射技术在核酸分析中的应用得到了迅速的发展。核酸的共振光散射分析方法可以用普通的荧光分光光度计进行测定 ,应用安全、便宜的试剂获得很高的灵敏度。简要介绍了共振光散射分析的基本原理 ,并对近年来利用共振光散射技术分析核酸的研究进行了评述。内容主要包括利用有机染料分子作为核酸的共振光散射探针的分析方法 ;基于阳离子表面活性剂、金属离子及其络合物以及药物与核酸相互作用的分析方法 ;核酸形成大粒子的散射分析方法。     

N-Loop Treatment of Overlapping Diagrams by the Implicit Regularization Technique

We show how the Implicit Regularization Technique (IRT) can be used for the perturbative renormalization of a simple field theoretical model generally used as a test theory for new techniques. While IRT has been applied successfully in many problems involving symmetry-breaking anomalies and nonabelian gauge groups, all at one-loop level, this is the first attempt at a generalization of the technique for perturbative renormalization. We show that the overlapping divergent loops can be given a completely algebraic treatment. We display the connection between renormalization and counterterms in the Lagrangian. The algebraic advantages make IRT worth studying for perturbative renormalization of gauge theories.     

Particle Manipulation by Ultrasonic Standing Wave Fields to complement dynamic light scattering experiments

Dynamic light scattering is a widely used technique for the sizing of colloidal suspensions. It is capable of measuring particles across the size range from approximately 1 nm to several microns. However the larger particle sizes tend to pose problems for the interpretation of the scattered light signal either by virtue of their light scattering efficiency relative to the smaller species present or the departure of the scattered light signal from Gaussian statistics. Rapid removal of such particles in-situ could extend the use of dynamic light scattering particularly in on-line analysis or laboratory automated measurement. In this paper a method is demonstrated for the in-situ removal of larger particles in suspension by means of ultrasonic standing waves and concurrent dynamic light scattering measurement. The theory behind ultrasonic particle manipulation and its effect on the motion of the particles is discussed. Data from a scattering cell designed to incorporate the ultrasonic technology is presented showing that dynamic light scattering measurements may be carried out under such conditions. Varying the energy density of the ultrasonic field allows particles greater than a defined cut-off diameter to be removed from the measurement region. Theory shows that the minimum cut-off size may be as small as 100 nm. Results presented here demonstrate complete removal at a lower diameter threshold of approximately 2000 nm.     

Thermal wave photopyroelectric characterization of advanced materials: State of the art

This article reviews the history, background, theoretical basis, development, attempts to optimize, and experimental performance of the photopyroelectric technique for the optothermal characterization of advanced materials such as semiconductors, superconductors, pure metals and alloys, quantum wells, liquid crystals, paramagnetic and ferromagnetic materials, as well as solar cells. The state of the art in the experimental processes in this field is also reviewed. This new photothermal technique can be used after a careful optimization, as a highly sensitive method for photopyroelectric spectroscopy and general thermal wave measurements. It has been shown to be a highly sensitive spectroscopic method for the nondestructive evaluation of advanced materials. This review presents the main photopyroelectric theoretical models that have been used for the extraction of some important optoelectronic properties such as the optical absorption coefficient and the nonradiative quantum efficiency spectra, as well as some thermal properties such as the thermal diffusivity, thermal conductivity, and specific heat. The applicability of the general basic theoretical model with its many special cases is also described in detail. This review demonstrates how photopyroelectric spectroscopy can be complementary to the conventional spectroscopic methods. The different experimental modes of the technique are also discussed. Moreover, some ideas concerning future perspectives of applying the technique to other scientific fields are outlined. This article does not aspire to an in-depth analysis of the experimental results in the field; rather, it focuses on the technique itself.     

光交联技术的生物应用研究进展

光交联反应作为一种快速、简单和时空可控的交联工具广泛地应用于化学、生物、医学和材料等不同研究领域。本文详细介绍了常用的小分子光交联基团的结构、分类及反应机理,重点综述了光交联技术在生物医学领域的应用研究,并对其应用前景进行了展望。目前大多光交联基团仅对紫外和可见光具有敏感性,紫外和可见光穿透力弱、组织吸收强和散射等问题严重限制了该技术在生物体内的应用研究。因此,进一步研究光交联技术在生物体系的应用和开发长波长光(如近红外或远红外光)介导的新交联技术对于药物研发和疾病诊疗具有重要的科学意义。     

Full field automated evaluation of the quarter wave plate retardation by phase stepping technique

Quarter wave plates are optical elements commonly used in photoelasticity to obtain circularly polarized light. They divide the incident light field into two linearly polarized orthogonal components with a phase difference of a quarter of the light wavelength. Due to the tolerance in manufacturing, however, the actual phase shifting produced by the plates is affected by an error, which noticeably influences the photoelastic measurements performed by means of various automated methods. This paper presents a technique, based on the phase stepping method, for the full field automatic evaluation of the quarter wave plate error.     

Reconstruction of the density field using the Colored Background Oriented Schlieren Technique (CBOS)

In this paper the improved Background Oriented Schlieren technique called CBOS (Colored Background Oriented Schlieren) is described and used to reconstruct density fields of three-dimensional flows. The Background Oriented Schlieren technique (BOS) allows to measure the light deflection caused by density gradients in a compressible flow. For this purpose the local image displacements of the image of a background pattern observed through the flow is used. In order to increase the performance of the conventional Background Oriented Schlieren technique, the monochromatic background is replaced by a colored dot pattern. The different colors are treated separately using suitable correlation algorithms. Therefore, the accuracy and the spatial resolution can be increased. A tomographic reconstruction method is then used to reconstruct the density field in three-dimensional flows from CBOS measurements.     

基于图像部分加入的数字全息水印技术

提出了一种以数字全息为基础的数字水印技术,实现了在原始图像中嵌入数字全息水印.考虑到传统的数字全息水印提取过程简单、易受攻击,为了提高水印信息的安全性,对传统的方法进行了改进.采用了图像部分加入的方法,将水印添加位置、水印图像大小和水印添加位置边缘像素作为水印提取密钥.实验证明,运用这种方法添加的水印具有较高的安全性.     

航空成像系统检调焦技术分析与展望

介绍了航空成像系统的特殊工作环境及应用需求对检调焦技术的要求,讨论了当前3种主要检调焦方法：程序标定法,光学自准直法及图像对比度法,总结并比较了3种方法的检调焦精度、检调焦时间等性能指标。最后着重讨论了基于光场成像理论与光学系统离焦深度之间的关系,对基于光场成像原理的快速检调焦技术进行了深入的分析、讨论,并对该技术在航空成像系统的应用前景进行了展望分析。     

The Progress on Cataluminescence-Based Analytical SystemSCIEI北大核心CSCD

Cataluminescence(CTL) is a phenomenon of light radiation generated when analyte moleculars were oxidized by catalyst. In the past few decades, CTL has developed rapidly and become a promising detection technique, especially in gas sensing, and has attracted much attention of researchers for its potential versatile applications in emission control, public safety, and environmental protection. The analytical system based on CTL has low detection limit, high sensitivity and simple instrument which easy to operate, which shows huge advantages in the detection of inorganic gases and volatile organic compounds. The library of sensing materials has been greatly enriched to thousands kinds, which contains metals, metal/non-metal oxides, sulfide, metal salts, organic compounds, ceramic, glass and other types of materials; Composite materials have been developed; The decreasing of material dimensions to nanoscale provided new opportunities for its development; The morphology of material has also been explored. Some novel hyphenated techniques based on CTL coupled to other techniques including preconcentration/sepration, nebulization, plasma have been developed, as well as some new CTL technique including static CTL, cyclic CTL and ect. Thanks to development of sensing material and the appearance of these novel techniques, the selectivity and sensitivity of CTL system has been improved, and the range of CTL application has been extended. In this article, the progress made in the field of cataluminescence, especially in latest developments of analytical applications were reviewed. The catalysts used in CTL, the recent novel CTL techniques were sumerized. The future of the cataluminescence was also forecasted.