Electron Backscatter Diffraction in Materials Science,9780306464874

Electron Backscatter Diffraction in Materials Science

by ; ;
ISBN13: 9780306464874
ISBN10: 030646487X
Format: Hardcover
Pub. Date: 2000-08-01
Publisher(s): Kluwer Academic Pub
List Price: $175.00

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Summary

Crystallographic texture or preferred orientation has long been known to strongly influence material properties. Historically, the means of obtaining such texture data has been though the use of x-ray or neutron diffraction for bulk texture measurements, or transmission electron microscopy (TEM) or electron channeling for local crystallographic information. In recent years, we have seen the emergence of a new characterization technique for probing the microtexture of materials. This advance has come about primarily through the automated indexing of electron backscatter diffraction (EBSD) patterns. The first commercially available system was introduced in 1994, and since then the growth of sales worldwide has been dramatic. This has accompanied widening applicability in materials science problems such as microtexture, phase identification, grain boundary character distribution, deformation microstructures, etc. and is evidence that this technique can, in some cases, replace more time-consuming TEM or X-ray diffraction investigations. The purpose of this book is to provide the fundamental basis for EBSD. The formation and interpretation of EBSD patterns and the gnomonic projection are described as the framework for materials characterization using EBSD. Traditional representation of texture in orientation space is discussed in terms of stereographic projections, pole figures, inverse pole figures, and orientation distribution functions before introducing the Rodrigues-Frank representation of crystallographic texture. The fundamentals of automated EBSD and the accuracy of EBSD measurements are then discussed. Current hardware and software as well as future prospects for analyzing EBSD data sets are reviewed. A brief mention of the criterion required for the purchase of an EBSD system is included as an aid to this relatively new area of materials characterization. The section concludes with chapters from three manufacturers of EBSD equipment that highlight recent advances in capabilities. The book concludes with a review of recent applications of the technique to solve difficult problems in materials science as well as demonstrates the usefulness of coupling EBSD with other approaches such as numerical analysis, plasticity modeling, and TEM. Attention is paid to the measurement and mapping of strain using EBSD as well as the characterization of deformed microstructures, continuous recrystallization, analysis of facets, ceramics, and superconducting materials.

Table of Contents

The Development of Automated Diffraction in Scanning and Transmission Electron Microscopy
1(18)
David J. Dingley
Abstract
1(1)
Preface
1(1)
The earliest work
2(2)
The first diffraction experiments in the SEM
4(1)
Computer assisted indexing of EBSD
5(2)
Fully automated indexing of EBSD patterns
7(1)
Orientation imaging microscopy
7(2)
EBSD image quality
9(2)
EBSD, spatial resolution
11(2)
EBSD for phase identification
13(1)
The move to the transmission electron microscope
14(2)
Conclusions
16(3)
Theoretical Framework for Electron Backscatter Diffraction
19(12)
Valerie Randle
Introduction
19(1)
Formation and interpretation of the EBSD Kikuchi patterns
20(5)
Crystallographic terms of reference for EBSD
25(3)
Descriptors of orientation and misorientation
28(2)
Concluding remarks
30(1)
Representations of Texture in Orientation Space
31(8)
Krishna Rajan
Introduction
31(1)
Stereographic projections
31(1)
Pole figures from EBSD
32(1)
Inverse pole figures from EBSD
33(1)
Orientation distribution functions and Euler space
34(3)
Conclusions
37(2)
Rodrigues-Frank Representations of Crystallographic Texture
39(12)
Krishna Rajan
Introduction
39(1)
Geometrical characteristics of Rodrigues-Frank space
40(2)
Fiber textures
42(2)
Lattice symmetry-sample symmetry coupling
44(2)
Crystallographic statistics and clustering in R-F space
46(1)
Grain boundary texture
47(2)
Conclusions
49(2)
Fundamentals of Automated EBSD
51(14)
Stuart I. Wright
Abstract
51(1)
Image processing
51(2)
Zone axis indexing
53(1)
Band detection
53(5)
Automatic indexing
58(2)
Structure definition
60(1)
Calibration
61(4)
Studies on the Accuracy of Electron Backscatter Diffraction Measurements
65(10)
Melik C.Demirel
Bassem S. El-Dasher
Brent L. Adams
Anthony D. Rollett
Abstract
65(1)
Introduction
65(1)
Definition of disorientation correlation function (DCF)
66(2)
Accuracy of orientation measurements
68(1)
Results
68(5)
Discussion
73(1)
Summary
74(1)
Phase Identification Using Electron Backscatter Diffraction in the Scanning Electron Microscope
75(16)
Joseph R. Michael
Introduction
75(1)
Phase identification procedure
76(2)
Examples of phase identification studies
78(2)
Structure determination from EBSD patterns
80(8)
Summary
88(3)
Three-Dimensional Orientation Imaging
91(14)
Dorte Juul Jensen
Introduction
91(1)
The 3D x-ray diffraction microscope
92(2)
Orientation determination
94(2)
Applications
96(6)
Summary
102(3)
Automated Electron Backscatter Diffraction: Present State and Prospects
105(18)
Robert A. Schwarzer
Introduction
105(1)
The interpretation of backscatter Kikuchi patterns
106(4)
Experimental setup of a modern EBSD system
110(1)
The components of an automated EBSD system
111(9)
The evaluation of grain orientation data
120(3)
EBSD:Buying a System
123(4)
Alwyn Eades
Should you build your own system?
123(1)
What camera should you use?
124(1)
Which is the best microscope for EBSD?
124(1)
Which software?
125(1)
Software criteria
125(1)
Conclusion
126(1)
Hardware and Software Optimization for Orientation Mapping and Phase Identification
127(8)
Patrick P. Camus
Abstract
127(1)
Background
127(1)
Crystal orientation mapping optimizations
128(3)
Phase identification optimization
131(2)
EBSD options
133(1)
Conclusions
133(2)
An Automated EBSD Acquisition and Processing System
135(6)
Pierre Rolland
Keith G. Dicks
Introduction
135(1)
Electron image and pattern acquisition
135(5)
Data Processing
140(1)
Advanced Software Capabilities for Automated EBSD
141(12)
Stuart I. Wright
David P. Field
David J. Dingley
Introduction
141(1)
Data collection
141(5)
Data analysis
146(6)
Summary
152(1)
Strategies for Analyzing EBSD Datasets
153(18)
Wayne E. King
James S. Stolken
Mukul Kumar
Adam J. Schwartz
Introduction
153(1)
Data analysis strategies: 2-D
153(12)
Data analysis strategies: 3-D
165(6)
Structure-Property Relations: EBSD-Based Material-Sensitive Design
171(10)
Brent L. Adams
Benjamin L. Henrie
Larry L. Howell
Richard J. Balling
Introduction
171(1)
Structure-properties relationships
172(4)
Material sensitive design
176(3)
Summary and conclusions
179(2)
Use of EBSD Data in Mesoscale Numerical Analyses
181(18)
Richard Becker
Hasso Weiland
Introduction
181(1)
Crystal plasticity model
182(5)
Crystal model validation
187(8)
Discussion
195(4)
Characterization of Deformed Microstructures
199(14)
David P. Field
Hasso Weiland
Introduction
199(2)
Cold-rolled pure aluminum
201(4)
Equal-channel extruded and cold-rolled copper
205(2)
Friction stir welding in aluminum
207(3)
Discussion
210(3)
Anisotropic Plasticity Modeling Incorporating EBSD Characterization of Tantalum and Zirconium
213(18)
John F. Bingert
Thomas A. Mason
George C. Kaschner
Paul J.Maudlin
George T. Gray III
Introduction
213(1)
Tantalum
214(7)
Zirconium
221(6)
Conclusions
227(4)
Measuring Strains Using Electron Backscatter Diffraction
231(16)
Angus J. Wilkinson
Scope of chapter
231(1)
Introduction
231(2)
Plastic deformation
233(5)
Elastic deformation
238(6)
Concluding remarks
244(3)
Mapping Residual Plastic Strain in Materials Using Electron Backscatter Diffraction
247(18)
Edward M. Lehockey
Yang-Pi Lin
Olev E. Lepik
Introduction
247(1)
Misorientation density distributions
248(2)
Quantifying strains by misorientation density
250(6)
Mapping the spatial distribution of strain fields
256(2)
Applications
258(5)
Summary
263(2)
EBSD Contra TEM Characterization of a Deformed Aluminum Single Crystal
265(12)
Xiaoxu Huang
Dorte Juul Jensen
Introduction
265(2)
Experimental procedures
267(1)
Results
267(7)
Discussions
274(1)
Summary and general remark
275(2)
Continuous Recrystallization and Grain Boundaries in a Superplastic Aluminum Alloy
277(14)
Terry R. McNelley
Introduction
277(2)
The material and method of EBSD examination
279(2)
The grain boundary character of Supral 2004
281(3)
Discussion
284(4)
Conclusion
288(3)
Analysis of Facets and Other Surface Using Electron Backscatter Diffraction
291(8)
Valerie Randle
Introduction
291(1)
Investigation methodology
291(5)
Data analysis
296(1)
Three-dimensional microtexture
297(1)
Concluding remarks
298(1)
EBSD of Ceramic Materials
299(20)
Jeffrey K. Farrer
Joseph R. Michael
C. Barry Carter
Introduction
299(1)
Challenge of ceramic materials for EBSD
300(3)
Examples of applications to ceramics
303(1)
Similar problems
303(3)
Special problems for ceramics
306(2)
Thin-film reactions
308(4)
Grain boundary migration
312(2)
Grain boundary energies grooving
314(1)
Summary
315(1)
Conclusions
316(3)
Grain Boundary Character Based Design of Polycrystalline High Temperature Superconducting Wires
319(18)
Amit Goyal
Introduction
319(1)
Background
320(2)
First generation HTS wires
322(6)
Second generation HTS wires
328(5)
Summary
333(4)
Index 337

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