用网格衰减膜相对标定SIOFM—5FW软X光底片

点降焦激光等离子体发出的Ｘ射线经晶体色散形成均匀的单色Ｘ射线源，在此基础上，用单层网格作为衰减膜，得到未经衰减和经过衰减的Ｘ射线谱，对无保护膜的ＳＩＯＦ－Ｍ５ＦＷ软Ｘ光底片作了试验性的相对标定，得到了０．９１ｎｍ波长的特性曲线。     

用平场光栅谱仪现场标定5FW X光底片

采用像散模式的平场光栅谱仪作为分光元件，点状镁激光等离子体Ｘ射线源为原始光源，获得均匀线性单色较Ｘ射线再生源，在此基础上，用多阶梯衰减膜为相对曝光强度标尺，现场标定了上海感光胶片厂生产的５ＦＷ无保护膜Ｘ光底片，给出了５．０ｎｍ～８．０ｎｍ间的底片响应特性。     

X射线荧光光谱分析的现状和进展

本文综述了常规Ｘ射线荧光（ＸＲＦ）、同步辐射ＸＲＦ，全反射ＸＲＦ和其他ＸＲＦ等四个方面的ＸＲＦ光谱分析的现状和进展。     

一种可用于测量薄膜材料的实验室EXAFS方法

本文介绍了利用从薄膜衬底反射的Ｘ射线，在常规实验室条件下实现了对薄膜材料的ＥＸＡＦＳ测量．我们用该方法在 Ｄ／ｍａｘ－ｒＢ１２ｋＷ转靶Ｘ射线衍射仪上得到的纯 Ｃｕ薄膜的 ＥＸＡＦＳ测量结果和常规透射法的测量结果一致．这表明该方法是可靠的．     

X射线皮秒分幅相机在强X射线情况下的应用研究

扫描型变象管Ｘ射线皮秒分幅相机在强Ｘ射线情况下，由于空间电荷效应，像质变坏，甚至无法工作。本文简述了ＭｇＦ光阴极材料的性能。首次在Ｘ射线皮秒变象管分幅相机上的应用结果：降低了强Ｘ射线源情况下分幅管内空间电荷效应的影响，并获得了清晰的物理图像。     

X射线荧光光谱分析氟化铈晶体中掺杂元素钕

本文提出了用Ｘ射线荧光光谱定量分析氟化铈晶体中掺杂元素钕方法，对用ＸＲＦＳ进行晶体样品分析时的制样方法作了比较，并且对用ＸＲＦＳ非破坏分析晶体中的掺杂元素的方法进行了探讨。     

BaFBr，BaFBr：Eu~（2＋）和BaFBr：Ce~（3＋）晶体在X射线辐照和光激励过程中发光和光电导的实时原位测量

在自建的多功能实时原位测量发光特性和光电导的实验装置上，测量了ＢａＦＢｒ，ＢａＦＢｒ：Ｅｕ２＋和ＢａＦＢｒ：Ｃｅ３＋单晶在Ｘ射线辐照和光激励过程中的发光强度和光电导。首次从光电导的角度测量到Ｘ射线辐照时，Ｅｕ２＋并没有被离化，而Ｃｅ３＋被离化，离化电子经导带被Ｆ＋心俘获；明确证实了光激励过程中Ｆ心电子的隧穿效应。     

遗传算法在EXAFS谱图解析中的应用

扩展Ｘ射线吸收精细结构（ＥＸＡＦＳ）谱是研究物质原子近邻结构和表面结构的有力工具。ＥＸＡＦＳ谱的解析通常采用标准样品比较法或最小二乘曲线拟合方法。但前者对标样的要求很高，而后者则参数初值难以确定，且结果有时不唯一。本文提出一种ＥＸＡＦＳ曲线拟合的新方法一遗传算法，并对单配位层Ｃｕ样品的ＥＸＡＦＳ谱图进行了解析，取得满意的结果。     

Fe掺杂的LaBa2Cu3O7的晶体微结构

本文应用Ｒｉｅｔｖｅｌｄ精修方法对高浓度Ｆｅ掺杂的ＬａＢａ２Ｃｕ３Ｏｄ（ＬＢＣＯ）超导体的Ｘ射线衍射谱进行了仔细的分析，得到了各掺杂样品的品格参数和原子结构参数，结果表明，Ｆｅ掺杂诱导了ＬＢＣＯ晶格的结构相变，随着Ｆｅ浓度的增加，出现了从正交到四方再到正交的结构震荡。     

石棉红花岗石与芝麻白花岗石的光谱的研究

本文用电感耦合等离子体原子发射光谱法，Ｘ射线荧光光谱法、红外光谱以及Ｘ射线衍射谱测定了石棉红花岗石和芝麻白花岗石的成分和光谱、根据石棉红岗石和芝麻白花岗石的Ｘ射线衍射谱，用计算机检索它们的组成，对计算机检索的结果进行对比得出，石棉红花岗石的红色是由于它含有Ｆｅ的红色矿物而产生的。     

Hard X‐ray microbeam lithography using a Fresnel zone plate with a long focal length

Focused hard X‐ray microbeams for use in X‐ray nanolithography have been investigated. A 7.5 keV X‐ray beam generated at an undulator was focused to about 3 µm using a Fresnel zone plate fabricated on silicon. The focused X‐ray beam retains a high degree of collimation owing to the long focal length of the zone plate, which greatly facilitates hard X‐ray nanoscale lithography. The focused X‐ray microbeam was successfully utilized to fabricate patterns with features as small as 100 nm on a photoresist.     

X‐ray spectra by means of Monte Carlo simulations for imaging applications

X‐ray tubes have a broad range of applications worldwide, including several techniques for atomic physics, like X‐ray fluorescence, as well as for medical imaging, like computed tomography. The performances of X‐ray imaging detectors have shown to be significantly sensitive to the incident beam spectrum. Therefore, an accurate knowledge of the X‐ray beam becomes necessary for the emission source characterization and the whole imaging process comprehension. Direct measurements and suitable Monte Carlo simulations may be used to establish the X‐ray spectra. Dedicated Monte Carlo simulation routines, based on the PENELOPE code, have been developed to determine the Bremsstrahlung X‐ray spectra generated by conventional X‐ray tubes. The simulated spectra have been validated by comparison with the corresponding experimental data showing an overall good agreement. The incorporation of a suitably designed virtual grid allowed to assess the angular distribution of Bremsstrahlung yield, showing a remarkable anisotropy. In addition, a dedicated program has been developed for virtual imaging, which enables to perform suitable X‐ray absorption contrast images. Also, the developed program includes a user‐friendly graphic interface to allow the upload of required input parameters, which include setup arrangement, beam characteristics, sample properties and image simulation parameters (spatial resolution, tracks per run, etc.). The software includes dedicated subroutines which handle the physical process from X‐ray generation up to detector signal acquisition. The aim of the developed program is to perform virtual imaging by means of absorption contrast and using conventional X‐ray sources, which may be a useful tool for the study the X‐ray imaging techniques in several research fields as well as for educational purposes. The performed comparisons with experimental data have shown good agreement. The obtained results for X‐ray imaging may constitute useful information for the comprehension and improvement of X‐ray image quality, like absorption contrast optimization, detail visualization, definition and detectability. Copyright © 2010 John Wiley & Sons, Ltd.     

Tests and characterization of a laterally graded multilayer Montel mirror

Multilayers are becoming an increasingly important tool in X‐ray optics. The essential parameters to design a pair of laterally graded multilayer mirrors arranged in a Montel‐type configuration for use as an X‐ray collimating device are provided. The results of X‐ray reflectometry tests carried out on the optics in addition to metrology characterization are also shown. Finally, using experimental data and combined with X‐ray tracing simulations it is demonstrated that the mirror meets all stringent specifications as required for a novel ultra‐high‐resolution inelastic X‐ray scattering spectrometer at the Advanced Photon Source.     

0.5 mm金刚石X射线相位延迟板及偏振度的标定

在利用步辐射光源的偏振特性进行自旋相关X射线散射及吸收谱实验来研究材料的磁学性质时，需要应用圆偏振光，这就提出了对具有高通量、高偏振度' 长连续可调的圆偏振X射线的需求；另一方面标定实验所用X射线的圆偏振度也成为这一研究领域的关键技术。由于X射线多光束衍射强度与σ场和π场的光程差δ相关，通过测量圆偏振分析晶体的多光束衍射的强度分布，可以获得入射X射线的圆偏振度。实验在美国国家同步辐射光源实验室X25光束线实验站进行，光子能量为7．1keV的圆偏振X射线由线偏振X射线经过一厚度为0．5mm、晶面为[111]的金刚石晶体产生。通过测量多光束衍射强度，确定了斯托克斯参量。实验值与X射线动力学理论计算结果能较好地吻合。     

X‐ray spectromicroscopy in soil and environmental sciences

X‐ray microscopy is capable of imaging particles in the nanometer size range directly with sub‐micrometer spatial resolution and can be combined with high spectral resolution for spectromicroscopy studies. Two types of microscopes are common in X‐ray microscopy: the transmission X‐ray microscope and the scanning transmission X‐ray microscope; their set‐ups are explained in this paper. While the former takes high‐resolution images from an object with exposure times of seconds or faster, the latter is very well suited as an analytical instrument for spectromicroscopy. The morphology of clusters or particles from soil and sediment samples has been visualized using a transmission X‐ray microscope. Images are shown from a cryo‐tomography experiment based on X‐ray microscopy images to obtain information about the three‐dimensional structure of clusters of humic substances. The analysis of a stack of images taken with a scanning transmission X‐ray microscope to combine morphology and chemistry within a soil sample is shown. X‐ray fluorescence is a method ideally applicable to the study of elemental distributions and binding states of elements even on a trace level using X‐ray energies above 1 keV.     

Analysis and interpretation of the first monochromatic X‐ray tomography data collected at the Australian Synchrotron Imaging and Medical beamline

The first monochromatic X‐ray tomography experiments conducted at the Imaging and Medical beamline of the Australian Synchrotron are reported. The sample was a phantom comprising nylon line, Al wire and finer Cu wire twisted together. Data sets were collected at four different X‐ray energies. In order to quantitatively account for the experimental values obtained for the Hounsfield (or CT) number, it was necessary to consider various issues including the point‐spread function for the X‐ray imaging system and harmonic contamination of the X‐ray beam. The analysis and interpretation of the data includes detailed considerations of the resolution and efficiency of the CCD detector, calculations of the X‐ray spectrum prior to monochromatization, allowance for the response of the double‐crystal Si monochromator used (via X‐ray dynamical theory), as well as a thorough assessment of the role of X‐ray phase‐contrast effects. Computer simulations relating to the tomography experiments also provide valuable insights into these important issues. It was found that a significant discrepancy between theory and experiment for the Cu wire could be largely resolved in terms of the effect of the point‐spread function. The findings of this study are important in respect of any attempts to extract quantitative information from X‐ray tomography data, across a wide range of disciplines, including materials and life sciences.     

Status of the hard X‐ray microprobe beamline ID22 of the European Synchrotron Radiation Facility

The ESRF synchrotron beamline ID22, dedicated to hard X‐ray microanalysis and consisting of the combination of X‐ray fluorescence, X‐ray absorption spectroscopy, diffraction and 2D/3D X‐ray imaging techniques, is one of the most versatile instruments in hard X‐ray microscopy science. This paper describes the present beamline characteristics, recent technical developments, as well as a few scientific examples from recent years of the beamline operation. The upgrade plans to adapt the beamline to the growing needs of the user community are briefly discussed.     

我国同步辐射小角X光散射装置

小角X光散射是当X光照射到物质上时发生的在原光束附近小角度范围内的电子相干散射,凡是存在纳米尺度的电子密度不均匀区的物质均会产生小角X光散射现象,因此它是表征纳米、多孔材料结构的理想手段。普通X光源产生的X光强度弱,限制了小角X光散射的应用,采用同步辐射为X光源,则可以大大提高X光强度。目前我国已建立同步辐射小角X光散射站,本文对其装置进行了介绍。     

The Munich Compact Light Source: initial performance measures

While large‐scale synchrotron sources provide a highly brilliant monochromatic X‐ray beam, these X‐ray sources are expensive in terms of installation and maintenance, and require large amounts of space due to the size of storage rings for GeV electrons. On the other hand, laboratory X‐ray tube sources can easily be implemented in laboratories or hospitals with comparatively little cost, but their performance features a lower brilliance and a polychromatic spectrum creates problems with beam hardening artifacts for imaging experiments. Over the last decade, compact synchrotron sources based on inverse Compton scattering have evolved as one of the most promising types of laboratory‐scale X‐ray sources: they provide a performance and brilliance that lie in between those of large‐scale synchrotron sources and X‐ray tube sources, with significantly reduced financial and spatial requirements. These sources produce X‐rays through the collision of relativistic electrons with infrared laser photons. In this study, an analysis of the performance, such as X‐ray flux, source size and spectra, of the first commercially sold compact light source, the Munich Compact Light Source, is presented.     

Analysis of the halo background in femtosecond slicing experiments

The slicing facility FemtoSpeX at BESSY II offers unique opportunities to study photo‐induced dynamics on femtosecond time scales by means of X‐ray magnetic circular dichroism, resonant and non‐resonant X‐ray diffraction, and X‐ray absorption spectroscopy experiments in the soft X‐ray regime. Besides femtosecond X‐ray pulses, slicing sources inherently also produce a so‐called `halo' background with a different time structure, polarization and pointing. Here a detailed experimental characterization of the halo radiation is presented, and a method is demonstrated for its correct and unambiguous removal from femtosecond time‐resolved data using a special laser triggering scheme as well as analytical models. Examples are given for time‐resolved measurements with corresponding halo correction, and errors of the relevant physical quantities caused by either neglecting or by applying a simplified model to describe this background are estimated.