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Advances in X-Ray Spectroscopy covers topics relevant to the advancement of X-ray spectroscopy technology. The book is a collection of papers written by specialists in X-ray spectroscopy and pays tribute to the scientific work of Prof. Yvette Cauchois. The text is organized into four parts. Part I covers the analysis of X-ray transitions between atomic levels and relativistic theories of X-ray emission satellites and electron BremsStrahlung. Part II reviews the means provided by X-ray spectroscopy for the determination of the electronic structure of solids, while Part III discusses methods of ...
The papers presented in this volume of Advances in X-Ray Analysis were chosen from those presented at the Fourteenth Annual Conference on the Applications of X-Ray Analysis. This conference, sponsored by the Metallurgy Division of the Denver Research Institute, University of Denver, was held on August 24,25, and 26, 1965, at the Albany Hotel in Denver, Colorado. Of the 56 papers presented at the conference, 46 are included in this volume; also included is an open discussion held on the effects of chemical com bination on X-ray spectra. The subjects presented represent a broad scope of applications of X-rays to a variety of fields and disciplines. These included such fields as electron-probe microanalysis, the effect of chemical combination on X-ray spectra, and the uses of soft and ultrasoft X-rays in emission analysis. Also included were sessions on X-ray diffraction and fluor escence analysis. There were several papers on special topics, including X-ray topography and X-ray absorption fine-structure analysis. William L. Baun contributed considerable effort toward the conference by organizing the session on the effect of chemical combination on X-ray spectra fine structure. A special session was established through the excellent efforts of S. P. Ong on the uses and applica tions of soft X-rays in fluorescent analysis. We offer our sincere thanks to these men, for these two special sessions contributed greatly to the success of the conference.
With contributions by Paul F. Fewster and Christoph Genzel While X-ray diffraction investigation of powders and polycrystalline matter was at the forefront of materials science in the 1960s and 70s, high-tech applications at the beginning of the 21st century are driven by the materials science of thin films. Very much an interdisciplinary field, chemists, biochemists, materials scientists, physicists and engineers all have a common interest in thin films and their manifold uses and applications. Grain size, porosity, density, preferred orientation and other properties are important to know: whether thin films fulfill their intended function depends crucially on their structure and morphology once a chemical composition has been chosen. Although their backgrounds differ greatly, all the involved specialists a profound understanding of how structural properties may be determined in order to perform their respective tasks in search of new and modern materials, coatings and functions. The author undertakes this in-depth introduction to the field of thin film X-ray characterization in a clear and precise manner.
The application of solid-state detectors of high energy resolution to x-ray spectrometry, and the increasing use of compu ters in both measurement and data evaluation, are giving a new stimulus to x-ray techniques in analytical chemistry. The Twentieth Annual Denver X-ray Conference reflects this renewed interest in several ways. The invited papers, grouped in Session I, review the charac teristics of the detectors used in the measurement of x-rays. One paper is dedicated to the detection of single ions. Although such a subject may appear to be marginal to the purposes of the Denver Conference, we must recognize the affinity of techniques applied to similar purposes. Ion probe mass spectrometry is dedicated to tasks similar to those performed by x-ray spectrometry with the electron probe microanalyzer. Scientists and technologists will see these two techniques discussed in the same meetings. The discussion of automation and programming is not limited to the two invited speakers, but extends to papers presented in more than one session. The matter of fluorescence analysis by isotope- and tube-excitation will also be of great interest to those concerned with the practical applications of x-ray techniques. The communications contained in this volume, and the lively discussions which frequently followed the presentation of papers, attest to the vitality of the subjects which are the concern of the Annual Denver X-ray Conference.
The application of solid-state detectors of high energy resolution to x-ray spectrometry, and the increasing use of compu ters in both measurement and data evaluation, are giving a new stimulus to x-ray techniques in analytical chemistry. The Twentieth Annual Denver X-ray Conference reflects this renewed interest in several ways. The invited papers, grouped in Session I, review the charac teristics of the detectors used in the measurement of x-rays. One paper is dedicated to the detection of single ions. Although such a subject may appear to be marginal to the purposes of the Denver Conference, we must recognize the affinity of techniques applied to similar purposes. Ion probe mass spectrometry is dedicated to tasks similar to those performed by x-ray spectrometry with the electron probe microanalyzer. Scientists and technologists will see these two techniques discussed in the same meetings. The discussion of automation and programming is not limited to the two invited speakers, but extends to papers presented in more than one session. The matter of fluorescence analysis by isotope- and tube-excitation will also be of great interest to those concerned with the practical applications of x-ray techniques. The communications contained in this volume, and the lively discussions which frequently followed the presentation of papers, attest to the vitality of the subjects which are the concern of the Annual Denver X-ray Conference.
This book provides a comprehensive, theoretical, practical, and thorough guide to current X-ray absorption fine structure (XAFS) spectroscopy and modern applications. It contains the experimental and theoretical aspects of XAFS in 14 chapters based on recent developments in the XAFS approach to science and technology, describing the basic principles and theories, calculation methods, computer programs, advanced methodologies and techniques, experiments, data analysis and interpretation and applications. Among the broad XAFS subjects of synchrotron radiation applications, the book specifically covers EXAFS, XANES and NEXAFS, AXAFS, DAFS, XMCD, MEXAFS, XMLD, and X-ray natural dichroism (XNCD and XNLD). This book may serve as a reference book for researchers and technicians taking up synchrotron radiation application research and postgraduates majoring in the X-ray absorption spectroscopy field. It will provide the beginners with all the necessary information in the field of XAFS. Also, experienced users active in particular subfields of XAFS spectroscopies will learn in this book about the enormous potential of XAFS for other applications in physics, chemistry, biology, materials science and engineering, geo- and environmental science, etc. For more details, please visit https: //centralwestpublishing.com s book provides a comprehensive, theoretical, practical, and thorough guide to current X-ray absorption fine structure (XAFS) spectroscopy and modern applications. It contains the experimental and theoretical aspects of XAFS in 14 chapters based on recent developments in the XAFS approach to science and technology, describing the basic principles and theories, calculation methods, computer programs, advanced methodologies and techniques, experiments, data analysis and interpretation and applications. Among the broad XAFS subjects of synchrotron radiation applications, the book specifically covers EXAFS, XANES and NEXAFS, AXAFS, DAFS, XMCD, MEXAFS, XMLD, and X-ray natural dichroism (XNCD and XNLD).
This book brings together a total of 48 contributions (including 5 keynote papers) which were presented at the 2nd International Workshop on the Application of X-ray CT for Geomaterials (GeoX 2006) held in Aussois, France, on 4-7 October, 2006. The contributions cover a wide range of topics, from fundamental characterization of material behavior to applications in geotechnical and geoenvironmental engineering. Recent advances of X-ray technology, hardware and software are also discussed. As such, this will be valuable reading for anyone interested in the application of X-ray CT to geomaterials from both fundamental and applied perspectives.
An indispensable resource for researchers and students in materials science, chemistry, physics, and pharmaceuticals Written by one of the pioneers of 2D X-Ray Diffraction, this updated and expanded edition of the definitive text in the field provides comprehensive coverage of the fundamentals of that analytical method, as well as state-of-the art experimental methods and applications. Geometry convention, x-ray source and optics, two-dimensional detectors, diffraction data interpretation, and configurations for various applications, such as phase identification, texture, stress, microstructure analysis, crystallinity, thin film analysis, and combinatorial screening are all covered in detail. Numerous experimental examples in materials research, manufacture, and pharmaceuticals are provided throughout. Two-dimensional x-ray diffraction is the ideal, non-destructive analytical method for examining samples of all kinds including metals, polymers, ceramics, semiconductors, thin films, coatings, paints, biomaterials, composites, and more. Two-Dimensional X-Ray Diffraction, Second Edition is an up-to-date resource for understanding how the latest 2D detectors are integrated into diffractometers, how to get the best data using the 2D detector for diffraction, and how to interpret this data. All those desirous of setting up a 2D diffraction in their own laboratories will find the author’s coverage of the physical principles, projection geometry, and mathematical derivations extremely helpful. Features new contents in all chapters with most figures in full color to reveal more details in illustrations and diffraction patterns Covers the recent advances in detector technology and 2D data collection strategies that have led to dramatic increases in the use of two-dimensional detectors for x-ray diffraction Provides in-depth coverage of new innovations in x-ray sources, optics, system configurations, applications and data evaluation algorithms Contains new methods and experimental examples in stress, texture, crystal size, crystal orientation and thin film analysis Two-Dimensional X-Ray Diffraction, Second Edition is an important working resource for industrial and academic researchers and developers in materials science, chemistry, physics, pharmaceuticals, and all those who use x-ray diffraction as a characterization method. Users of all levels, instrument technicians and X-ray laboratory managers, as well as instrument developers, will want to have it on hand.
A complete introduction to x-ray microscopy, covering optics, 3D and chemical imaging, lensless imaging, radiation damage, and applications.