![]() The multi-volume series comprises articles and tables of data relevant to crystallographic research and to applications of crystallographic methods in all sciences concerned with the structure and properties of materials. International Tables for Crystallography is the definitive resource and reference work for crystallography. About International Tables for Crystallography If you have already registered and are using a computer listed in your registration details, please email assistance. Contact details for International Tables Figures 1a and b show the plan-view of the inverse pole figure map from EBSD and the preferred orientation for the inverse pole figure on the surface grains fabricated at 50 mA cm 2.Guided tour of International Tables Online.International Tables for Crystallography is available online as a full set of volumes through Wiley. The chapter concludes with several examples of applications taken from both the materials and geological literature, and brief ruminations on the future of the EBSD characterization technique. The program performs in user friendly form the different calculations and graphic analysis of Orientation Distribution Function (ODF), Pole Figures (PFs) and Inverse Pole Figures (IPFs). Commercial and open-source software solutions for data analysis are described as well as a number of commonly used data formats. The LaboTex software is the Windows 95/98/NT tool for complex and detailed analysis of crystallographic textures. To obtain accurate results it is crucial that the sample surface be properly prepared and a number of standard techniques for obtaining an optimal sample surface finish are described. STEREOPOLE is a software package for the analysis of x-ray diffraction pole-figures. Since EBSD produces orientations, several commonly used orientation representations and parametrizations are reviewed before explaining how the crystal orientation is extracted from the experimental patterns, using either Hough-transform-based feature extraction, or the whole-pattern-matching approaches known as dictionary indexing and spherical indexing. This is followed by a review of the kinematical and dynamical theories of electron scattering which, along with the detector geometry, can be used to predict EBSD patterns, including the diffuse background intensity. The chapter starts by describing the experimental geometry of the sample and detector inside the chamber of a scanning electron microscope (SEM). EBSD typically produces 2D maps (or 3D volumes in the case of serial sectioning) of the orientations of the constituent crystallites of a sample with respect to an external reference frame. This chapter provides an overview of the electron backscatter diffraction (EBSD) modality which, over the past thirty years, has become a core microstructure characterization technique in both the materials and geological fields. ![]()
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