Texture and Anisotropy of Polycrystals II
Published on 30. May 2005
Book
Hardback
486 pages
978-3-908451-09-9 (ISBN)
Description
Volume is indexed by Thomson Reuters CPCI-S (WoS).
Natural, as well as man-made, materials are often assumed to behave uniformly, exhibiting equal strength in all directions, because most of them have a polycrystalline structure. The anisotropy of the individual crystals, however, is smoothed out only in the presence of a large number of grains having a random distribution of orientations. In reality, there usually remains an anisotropy due to the existence of preferred orientations. Its magnitude depends upon the statistical distribution of grain orientations - the "crystallographic texture" or, more simply, the texture. -This governs the extremes, of the physical property of interest, which a single crystal of the material under consideration can exhibit in directional tests. Local variations in texture, as well as the arrangements and types of grain/phase boundaries, may give rise to inhomogeneous material properties. The texture also carries with it information on the history of a material's processing, use and misuse. A knowledge of the texture is a prerequisite for all quantitative techniques of materials characterization, and is based upon the interpretation of diffraction-peak intensities. It is also necessary to model the relationships between microstructural features and physical or mechanical properties. Therefore, the texture is of great value for quality control in a wide range of industrial applications, and in basic materials research.
Natural, as well as man-made, materials are often assumed to behave uniformly, exhibiting equal strength in all directions, because most of them have a polycrystalline structure. The anisotropy of the individual crystals, however, is smoothed out only in the presence of a large number of grains having a random distribution of orientations. In reality, there usually remains an anisotropy due to the existence of preferred orientations. Its magnitude depends upon the statistical distribution of grain orientations - the "crystallographic texture" or, more simply, the texture. -This governs the extremes, of the physical property of interest, which a single crystal of the material under consideration can exhibit in directional tests. Local variations in texture, as well as the arrangements and types of grain/phase boundaries, may give rise to inhomogeneous material properties. The texture also carries with it information on the history of a material's processing, use and misuse. A knowledge of the texture is a prerequisite for all quantitative techniques of materials characterization, and is based upon the interpretation of diffraction-peak intensities. It is also necessary to model the relationships between microstructural features and physical or mechanical properties. Therefore, the texture is of great value for quality control in a wide range of industrial applications, and in basic materials research.
Volume is indexed by Thomson Reuters CPCI-S (WoS).
Natural, as well as man-made, materials are often assumed to behave uniformly, exhibiting equal strength in all directions, because most of them have a polycrystalline structure. The anisotropy of the individual crystals, however, is smoothed out only in the presence of a large number of grains having a random distribution of orientations. In reality, there usually remains an anisotropy due to the existence of preferred orientations. Its magnitude depends upon the statistical distribution of grain orientations - the "crystallographic texture" or, more simply, the texture. -This governs the extremes, of the physical property of interest, which a single crystal of the material under consideration can exhibit in directional tests. Local variations in texture, as well as the arrangements and types of grain/phase boundaries, may give rise to inhomogeneous material properties. The texture also carries with it information on the history of a material's processing, use and misuse. A knowledge of the texture is a prerequisite for all quantitative techniques of materials characterization, and is based upon the interpretation of diffraction-peak intensities. It is also necessary to model the relationships between microstructural features and physical or mechanical properties. Therefore, the texture is of great value for quality control in a wide range of industrial applications, and in basic materials research.
More details
Series
Language
English
Place of publication
Zurich
Switzerland
Target group
College/higher education
Professional and scholarly
Dimensions
Height: 24.5 cm
Width: 17 cm
Thickness: 24 mm
Weight
1000 gr
ISBN-13
978-3-908451-09-9 (9783908451099)
DOI
10.4028/www.scientific.net/SSP.105
Schweitzer Classification
Other editions
Additional editions
Claude Esling | Michel Humbert | Robert A. Schwarzer
Texture and Anisotropy of Polycrystals II
E-Book
07/2005
Trans Tech Publications Ltd
€211.86
Available for download
Claude Esling | Michel Humbert | Robert A. Schwarzer
Texture and Anisotropy of Polycrystals II
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05/2005
Trans Tech Publications Ltd
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Shipment within 10-20 days
Content
<ul><li>Texture and Microstructure Imaging by the Moving Area Detector Method</li><li>On the Use of Texture Analysis and Orientation Stereology to Investigate Polycrystalline Materials </li><li>Texture in Hot Extruded, Hot Rolled and Laser Welded Magnesium Base Alloys</li><li>The Goss Texture Formation in Silicon Steels - Growth Selection or Oriented Nucleation? </li><li>Advances in Automatic TEM Based Orientation Mapping</li><li>Residual Strain Parameters Determinable from a CBED Pattern</li><li>Local Orientation Measurements in 3D</li><li>In Situ Texture Analysis Using Hard X-Rays </li><li>Residual Strain and Texture Measurements using Neutron-TOF-Diffraction on a Dolomite-Anhydrite Rock and a Quartz-Dunite Compound </li><li>EPSILON-MDS - A Neutron Time-of-Flight Diffractometer for Strain Measurements</li><li>Texture Analysis with Area Detectors</li><li>Study of Error Distribution in Measured Pole Figures</li><li>Use of Neutron Diffraction for Describing Texture of Isostatically-Pressed Molybdite Powders </li><li>Distribution of Dislocation Density in Tubes from Zr-Based Alloys by X-Ray Data </li><li>Reaction Stresses among the Grains during Tensile Deformation of Polycrystalline Metals </li><li>Texture Control in Manufacturing of ULSI Devices</li><li>Determination of Grain-Orientation-Dependent Stress in Coatings</li><li>On the Calculation of the Eshelby Tensor and the Beauty of our Nature</li><li>Crystallographic Relationships between FCC and BCC Crystals: A Study Using EBSD Techniques </li><li>? Microtexture Analysis in Correlation with HCP Textured Regions Observed in a Forged Near Alpha Titanium Alloy </li><li>Variant Selection in Zr Alloys: How Many Variants Generated from one Beta Grain? </li><li>Crystallographic Phase Composition and Structural Analysis of Ti-Ni-Fe Shape Memory Alloy by Synchrotron Diffraction </li><li>Variant Orientation Distribution in a Near-? Ti-Al Alloy with a Lamellar Microstructure </li><li>Texture Evolution In Fe-1%Si as a Function of High Magnetic Field</li><li>Local Orientation Gradient and Recrystallization of Deformed Copper</li><li>Grain Boundary Character and Pinning Effect during Grain Growth of Two-Phase Alloys </li><li>Electric Field Annealing on 3104 Aluminum Alloy Sheets: Evolution of Microstructure and Texture </li><li>Neutron Diffraction Texture Analysis of Grain-Oriented Steel Sheets</li><li>The Influence of Texture and GBCD on Stress Corrosion and Intergranular Corrosion in 2024 Aluminum Alloy </li><li>Calculation of Magnetization and Phase Equilibrium in Fe-C Binary System under a Magnetic Field </li><li>Deformation Textures in FCC Metals Subjected to Frictional and to Abrasive Wear </li><li>Influence of Starting Textures on the Development of Texture and Microstructure during Large Strain Hot Rolling of Pure Magnesium </li><li>Regular Substructure Inhomogeneity of Textured Materials by the Example of Rolled Ti-Ni Single Crystals </li><li>Effect of the 0.1% Sc Addition on the Texture Development and Mechanical Properties in Al-Zn-Mg-Cu-Mn Alloy </li><li>Dislocation Activity and Slip Analysis Contributing to Grain Boundary Sliding and Damage during Thermomechanical Fatigue in Dual Shear Lead-Free Solder Joint Specimens </li><li>The Effect of Texture on the Serrated Flow in Peak-Aged 2090 Al-Li Alloy</li><li>Cross-Sectional Texture Gradients in Interstitial Free Steels Processed by Accumulated Roll Bonding </li><li>Microstructure and Texture of Shear Bands in Cold Rolled Silicon Steel Single Crystals of Goss Orientation </li><li>A Sharp Cube Texture in Warm Rolled and Subsequently Annealed Silver Sheet </li><li>Simulation of Deformation Texture Evolution Using an Intermediate Model</li><li>Effect of Cooling Condition after Warm Rolling on the Development of Microstructure and Texture in an ELC Steel </li><li>A Rapid Deformation Texture Model Incorporating Grain Interactions: Application to Aluminium Hot Rolling Textures </li><li>A New Perspective on the Mathematical Modeling of Highly Nonlinear Anisotropic Plastic Flows in a Heterogeneous Solid </li><li>Correlation of Texture and Plastic Anisotropy in the Al-Mg Alloy AA 5005</li><li>Modeling Texture Evolution during Rolling of Magnesium Alloy AZ31</li><li>Texture Development in Nd-Fe-V and Nd-Fe-B Alloys by Hot Forging in View of Improving Permanent Magnet Properties </li><li>Texture Investigations of Zircaloy-4 Tubes by Neutron Diffraction </li><li>Shear Texture Formation during High-Strain Torsion of Titanium Aluminides</li><li>Microstructure and Texture in Copper Sheets after Reverse and Cross Rolling</li><li>Texture and Microstructure Evolution during Cold Swaging and Recrystallization of Oligocrystalline INCOLOY<sup> (R)</sup> MA 956 </li><li>Local and Global Effects in Texture and Microstructure Observed after Channel-Die Compression of Copper Single Crystals and after Cross-Rolling of Copper Sheets </li><li>Texture Gradient in ECAP Copper Measured by Synchrotron Radiation</li><li>Pure Ni Single Crystal of Cube Orientation Deformed by Equal Channel Angular Extrusion </li><li>Rolling Texture of ECAP Processed Al and Cu</li><li>Texture Evolution in FCC Metals during Equal Channel Angular Extrusion (ECAE) as a Function of Stacking Fault Energy </li><li>Oblique Cube Texture Formation in High Purity Aluminum during Equal Channel Angular Pressing </li><li>Texture Evolution in Commercially Pure Al during Equal Channel Angular Extrusion (ECAE) as a Function of Processing Routes </li><li>Strain Localization Observed during Shearing of Some Aluminium Alloys and Texture Softening Predicted by FC Taylor and Advanced Lamel Model </li><li>Simulating the Temper Rolling of Galvanized Steel</li><li>Quantifying Domain Textures in Lead Zirconate Titanate Using 022:202 and 220 Diffraction Peaks </li><li>Combined Analysis of Bi2223 Superconducting Bulk Materials</li><li>Effects of Dielectric Roughness on Texture of Both PVD Seed Layers and EP Copper </li><li>Texture Transition in Ag-Pd Alloy Substrate for Superconducting Tapes</li><li>Micro-Diffraction Studies of the Evolution of Textures in CVD-Grown Diamond Films </li><li>Temperature Dependence of the Texture of Sm-Co Thin Films</li><li>Aluminum Matrix Texture and Particle Characterization in Al-Al<sub>3</sub>Ti FGMs Produced by a Centrifugal Solid-Particle Method </li><li>Texture Analysis of CVD Free-Standing Diamond Films</li><li>Texture Measurements of Hydroxyapatite Crystallites at Bone-Implant Interfaces in Sheep Tibia </li><li>Growth Mechanism of Biaxially Aligned Magnesium Oxide Deposited by Unbalanced Magnetron Sputtering </li><li>Texture Analysis of Poly(vinyl Chloride) Foils</li><li>Biaxially Aligned Yttria Stabilized Zirconia and Titanium Nitride Layers Deposited by Unbalanced Magnetron Sputtering </li><li>Textured YBaCuO Films Enhanced by Cold Rolling and Melt Growth Process in Low Oxygen Partial Pressure </li><li>Textures of Ferroelectric BLT Films for Semiconductor Memories by Electron Backscatter Diffraction and Piezo-Response Force Microscope </li><li>Three-Dimensional Microstructure of Thin Copper Foils Revealed by Ion Beam Cutting and Electron Backscatter Diffraction (EBSD) </li></ul>