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The book is best used in the following sequence. (1) The radiation and method of recording are selected in accordance with the data of Chapters 1 and 2; the detailed param eters for the recording are defined. (2) The patterns are indexed with the assistance of the graphs and tables of Chapter 3. (3) The measured intensities are compared with the values found from the tables of Chapter 4. (4) The particular problem at hand (determi nation of stresses, phase analysis, and so on) is solved with the aid of the tables and nomo grams given in the second part of the book. The nomograms can be enlarged for use if necessary. This is not the only mode of use; in particular, the material in the appropriate chapter may be sufficient for a particular type of routine analysis. I have had the benefit of valuable advice from workers in various laboratories (Moscow State University, Moscow Steel Institute, the Institute of Crystallography, the Central Research Institute for Ferrous Metallurgy, the Technological Research Institute of the Automobile Industry, the Karpov Institute of Physical Chemistry, the All-Union Hard Alloys K~search Institute, and so on). In addition, I am deeply indebted for much assistance to Professor Ya. S. Umanskii (scientific editor), Professor V. I. Iveronova, Professor A. I. Kitaigorodskii, G. A. Gol'der, and V. I. Rydnik. I recognize that this work cannot be free from deficiencies, and I should like to thank in advance workers in x-ray laboratories who may offer criticisms.
The book is best used in the following sequence. (1) The radiation and method of recording are selected in accordance with the data of Chapters 1 and 2; the detailed param eters for the recording are defined. (2) The patterns are indexed with the assistance of the graphs and tables of Chapter 3. (3) The measured intensities are compared with the values found from the tables of Chapter 4. (4) The particular problem at hand (determi nation of stresses, phase analysis, and so on) is solved with the aid of the tables and nomo grams given in the second part of the book. The nomograms can be enlarged for use if necessary. This is not the only mode of use; in particular, the material in the appropriate chapter may be sufficient for a particular type of routine analysis. I have had the benefit of valuable advice from workers in various laboratories (Moscow State University, Moscow Steel Institute, the Institute of Crystallography, the Central Research Institute for Ferrous Metallurgy, the Technological Research Institute of the Automobile Industry, the Karpov Institute of Physical Chemistry, the All-Union Hard Alloys K~search Institute, and so on). In addition, I am deeply indebted for much assistance to Professor Ya. S. Umanskii (scientific editor), Professor V. I. Iveronova, Professor A. I. Kitaigorodskii, G. A. Gol'der, and V. I. Rydnik. I recognize that this work cannot be free from deficiencies, and I should like to thank in advance workers in x-ray laboratories who may offer criticisms.
This book presents a physical approach to the diffraction phenomenon and its applications in materials science. An historical background to the discovery of X-ray diffraction is first outlined. Next, Part 1 gives a description of the physical phenomenon of X-ray diffraction on perfect and imperfect crystals. Part 2 then provides a detailed analysis of the instruments used for the characterization of powdered materials or thin films. The description of the processing of measured signals and their results is also covered, as are recent developments relating to quantitative microstructural analysis of powders or epitaxial thin films on the basis of X-ray diffraction. Given the comprehensive coverage offered by this title, anyone involved in the field of X-ray diffraction and its applications will find this of great use.
Elementary crystallography. The production and properties of X-rays. Fundamental principles of X-ray diffraction. Photographic powder techniques. Diffractometric powder technique. The interpretation of powder diffraction data. Qualitative and quantitative analysis of crystalline powders. The precision determination of lattice constants. Crystallite size and lattice strains from line broadening. Investigation of preferred orientation and texture. Stress measurements in metals. Radial-distribution studies of noncrystalline materials. Layout for a diffraction laboratory. The handling and processing of X-ray film. Miscellaneous constants and numerical data. International atomic weights. Mass absorption coefficients u/p of the elements (Z=1 to 83) for a selection of wavelenghts. Quadratic forms for the cubic system. Atomic and ionic scattering factors. Lorentz and polarization factors. Temperature factor table. Warren's powder pattern power theorem.
Linking of materials properties with microstructures is a fundamental theme in materials science, for which a detailed knowledge of the modern characterization techniques is essential. Since modern materials such as high-temperature alloys, engineering thermoplastics and multilayer semiconductor films have many elemental constituents distributed in more than one phase, characterization is essential to the systematic development of such new materials and understanding how they behave in practical applications. X-ray techniques play a major role in providing information on the elemental composition and crystal and grain structures of all types of materials. The challenge to the materials characterization expert is to understand how specific instruments and analytical techniques can provide detailed information about what makes each material unique. The challenge to the materials scientist, chemist, or engineer is to know what information is needed to fully characterize each material and how to use this information to explain its behavior, develop new and improved properties, reduce costs, or ensure compliance with regulatory requirements. This comprehensive handbook presents all the necessary background to understand the applications of X-ray analysis to materials characterization with particular attention to the modern approach to these methods.
X-ray diffraction crystallography for powder samples is a well-established and widely used method. It is applied to materials characterization to reveal the atomic scale structure of various substances in a variety of states. The book deals with fundamental properties of X-rays, geometry analysis of crystals, X-ray scattering and diffraction in polycrystalline samples and its application to the determination of the crystal structure. The reciprocal lattice and integrated diffraction intensity from crystals and symmetry analysis of crystals are explained. To learn the method of X-ray diffraction crystallography well and to be able to cope with the given subject, a certain number of exercises is presented in the book to calculate specific values for typical examples. This is particularly important for beginners in X-ray diffraction crystallography. One aim of this book is to offer guidance to solving the problems of 90 typical substances. For further convenience, 100 supplementary exercises are also provided with solutions. Some essential points with basic equations are summarized in each chapter, together with some relevant physical constants and the atomic scattering factors of the elements.