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100   $a20100420d2010      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aCombined analysis$b[electronic resource] /$fDaniel Chateigner
205   $a1st edition
210   $aLondon, U.K. $cISTE ;$aHoboken, N.J. $cWiley$d2010
215   $a1 online resource (517 p.)
225 1 $aISTE
300   $aDescription based upon print version of record.
311   $a1-84821-198-8 
320   $aIncludes bibliographical references and index.
327   $aCover; Combined Analysis; Title Page; Copyright Page; Table of Contents; Introduction; Acknowledgements; Chapter 1. Some Basic Notions About Powder Diffraction; 1.1. Crystallite, grain, polycrystal and powder; 1.2. Bragg's law and harmonic reflections; 1.2.1. Bragg's law; 1.2.2. Monochromator; 1.2.3. Harmonic radiation components; 1.3. Geometric conditions of diffraction, Ewald sphere; 1.4. Imperfect powders; 1.5. Main diffraction line profile components; 1.5.1. Origin of g(x); 1.5.2. Origin of f(x); 1.5.3. Deconvolution-extraction of f(x) and g(x); 1.6. Peak profile parameters
327   $a1.7. Modeling of the diffraction peaks1.7.1. Why do we need modeling?; 1.7.2. Modeling of a powder diffraction pattern; 1.8. Experimental geometry; 1.8.1. Curved Position Sensitive detector, asymmetric reflection geometry; 1.8.2. CCD or image plate detector, transmission geometry; 1.8.3. Curved-Area Position-Sensitive detector, transmission geometry; 1.9. Intensity calibration (flat-field); 1.9.1. Counts and intensity; 1.9.2. Flat-field; 1.9.3. PSD detector; 1.9.4. CAPS detector; 1.10. Standard samples; 1.10.1. Laboratory x-ray standards; 1.10.2. Neutron texture standards
327   $a1.11. Probed thickness (penetration depth)Chapter 2. Structure Refinement by Diffraction Profile Adjustment (Rietveld Method); 2.1. Principle of the Rietveld method; 2.2. Rietveld-based codes; 2.3. Parameter modeling; 2.3.1. Background modeling; 2.3.2. Structure factor; 2.3.3. Crystallites' preferred orientation (texture) corrections; 2.3.4. Peak asymmetry; 2.3.5. Peak displacements; 2.3.6. Lorentz-polarization correction; 2.3.7. Volume, absorption, thickness corrections; 2.3.8. Localization corrections; 2.3.9. Microabsorption/roughness corrections; 2.3.10. Wavelength
327   $a2.4. Crystal structure databases2.5. Reliability factors in profile refinements; 2.6. Parameter exactness; 2.7. The Le Bail method; 2.8. Refinement procedures; 2.8.1. Least squares; 2.8.2. Genetic or evolutionary algorithms; 2.8.3. Derivative difference minimization (DDM); 2.8.4. Simulated annealing; 2.9. Refinement strategy; 2.10. Structural determination by diffraction; 2.10.1. The phase problem in diffraction; 2.10.2. Patterson function; 2.10.3. Direct methods; 2.10.4. Direct space methods; 2.10.5. Fourier difference map; 2.10.6. Extension to aperiodic structures
327   $aChapter 3. Automatic Indexing of Powder Diagrams3.1. Principle; 3.2. Dichotomy approach; 3.3. Criterions for quality; Chapter 4. Quantitative Texture Analysis; 4.1. Classic texture analysis; 4.1.1. Qualitative aspects of texture analysis; 4.1.2. Effects on diffraction diagrams; 4.1.3. Limitations of classic diagrams; 4.1.4. The Lotgering factor; 4.1.5. Representations of textures: pole figures; 4.1.6. Localization of crystallographic directions from pole figures; 4.1.7. Texture types; 4.2. Orientation distribution (OD) or orientation distribution function (ODF)
327   $a4.2.1. Pole figures and orientation spaces
330   $aThis book introduces and details the key facets of Combined Analysis - an x-ray and/or neutron scattering methodology which combines structural, textural, stress, microstructural, phase, layer, or other relevant variable or property analyses in a single approach. The text starts with basic theories related to diffraction by polycrystals and some of the most common combined analysis instrumental set-ups are detailed. Also discussed are microstructures of powder diffraction profiles; quantitative phase analysis from the Rietveld analysis; residual stress analysis for isotropic and anisotropic ma
410  0$aISTE
606   $aAnalytical chemistry
606   $aSolid state chemistry
606   $aCrystals
615  0$aAnalytical chemistry.
615  0$aSolid state chemistry.
615  0$aCrystals.
676   $a548.83
676   $a548/.83
700   $aChateigner$b Daniel$0896614
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910139243703321
996   $aCombined analysis$92003185
997   $aUNINA