Description

Book Synopsis

An indispensable resource for researchers and students in materials science, chemistry, physics, and pharmaceuticals

Written by one of the pioneers of 2D X-Ray Diffraction, this updated and expanded edition of the definitive text in the field provides comprehensive coverage of the fundamentals of that analytical method, as well as state-of-the art experimental methods and applications. Geometry convention, x-ray source and optics, two-dimensional detectors, diffraction data interpretation, and configurations for various applications, such as phase identification, texture, stress, microstructure analysis, crystallinity, thin film analysis, and combinatorial screening are all covered in detail. Numerous experimental examples in materials research, manufacture, and pharmaceuticals are provided throughout.

Two-dimensional x-ray diffraction is the ideal, non-destructive analytical method for examining samples of all kinds including metals, polymers, ceramics, semicon

Table of Contents

Preface xiii

1. Introduction 1

1.1 X-Ray Technology, a Brief History, 1

1.2 Geometry of Crystals, 2

1.3 Principles of X-Ray Diffraction, 11

1.4 Reciprocal Space and Diffraction, 13

1.5 Two-Dimensional X-Ray Diffraction, 19

References, 26

2. Geometry and Fundamentals 29

2.1 Introduction, 29

2.2 Diffraction Space and Laboratory Coordinates, 31

2.3 Detector Space and Detector Geometry, 35

2.4 Sample Space and Goniometer Geometry, 46

2.5 Transformation from Diffraction Space to Sample Space, 50

2.6 Reciprocal Space, 52

2.7 Summary, 53

References, 55

3. X-Ray Source and Optics 57

3.2 X-Ray Optics, 63

References, 85

4. X-Ray Detectors 87

4.1 History of X-Ray Detection Technology, 87

4.2 Point Detectors in Conventional Diffractometers, 89

4.3 Characteristics of Point Detectors, 92

4.4 Line Detectors, 100

4.5 Characteristics of Area Detectors, 107

4.6 Types of Area Detectors, 119

References, 137

5. Goniometer and Sample Stages 141

5.1 Goniometer and Sample Position, 141

5.2 Goniometer Accuracy, 145

5.3 Sample Alignment and Visualization Systems, 149

5.4 Environment Stages, 151

References, 155

6. Data Treatment 157

6.1 Introduction, 157

6.2 Non-Uniform Response Correction, 157

6.3 Spatial Correction, 161

6.4 Detector Position Accuracy and Calibration, 166

6.5 Frame Integration, 177

6.6 Multiple Frame Merge, 186

6.7 Scanning 2D Pattern, 194

6.8 Lorentz, Polarization, and Absorption Corrections, 197

References, 208

7. Phase Identification 211

7.1 Introduction, 211

7.2 Relative Intensity, 212

7.3 Geometry and Resolution, 216

7.4 Sampling Statistics, 221

7.5 Preferred Orientation Effect, 227

References, 233

8. Texture Analysis 235

8.1 Introduction, 235

8.2 Pole Density and Pole-Figure, 236

8.3 Fundamental Equations, 238

8.4 Data Collection Strategy, 242

8.5 Texture Data Process, 251

8.6 Orientation Distribution Function, 256

8.7 Fiber Texture, 261

8.8 Polymer Texture, 264

8.9 Other Advantages of XRD2 for Texture, 268

References, 269

9. Stress Measurement 271

9.1 Introduction, 271

9.2 Principle of X-ray Stress Analysis, 280

9.3 Theory of Stress Analysis with XRD2, 292

9.4 Process of Stress Measurement with XRD2, 307

9.5 Experimental Examples, 325

A9.1 Calculate Principal Stresses, 349

A9.2 Calculate the direction cosines for principal stresses (Eigenvectors), 350

References, 353

10. Small Angle X-ray Scattering 357

10.1 Introduction, 357

10.2 2D SAXS Systems, 361

10.3 Applications Examples, 367

10.4 Some Innovations in 2D SAXS, 370

References, 374

11. Combinatorial Screening 379

11.1 Introduction, 379

11.2 XRD2 Systems for High Throughput Screening, 380

11.3 Combined Screening with XRD2 and Raman, 390

Reference, 393

12. Miscellaneous Applications 395

12.1 Percent Crystallinity, 395

12.2 Crystal Size, 402

12.3 Retained Austenite, 412

12.4 Crystal Orientation, 414

12.5 Thin Film Analysis, 418

Reference, 429

13. Innovation and Future Development 433

13.1 Introduction, 433

13.2 Scanning Line Detector for XRD2, 434

13.3 Three-Dimensional Detector, 438

13.4 Pixel Direct Diffraction Analysis, 441

13.5 High Resolution Two-Dimensional X-Ray Diffractometer, 444

References, 451

Appendix A. Values of Commonly Used Parameters 453

Appendix B. Symbols 459

Index 465

Twodimensional Xray Diffraction

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    A Hardback by Bob B. He

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      Publisher: John Wiley & Sons Inc
      Publication Date: 03/08/2018
      ISBN13: 9781119356103, 978-1119356103
      ISBN10: 1119356105
      Also in:
      Chemistry

      Description

      Book Synopsis

      An indispensable resource for researchers and students in materials science, chemistry, physics, and pharmaceuticals

      Written by one of the pioneers of 2D X-Ray Diffraction, this updated and expanded edition of the definitive text in the field provides comprehensive coverage of the fundamentals of that analytical method, as well as state-of-the art experimental methods and applications. Geometry convention, x-ray source and optics, two-dimensional detectors, diffraction data interpretation, and configurations for various applications, such as phase identification, texture, stress, microstructure analysis, crystallinity, thin film analysis, and combinatorial screening are all covered in detail. Numerous experimental examples in materials research, manufacture, and pharmaceuticals are provided throughout.

      Two-dimensional x-ray diffraction is the ideal, non-destructive analytical method for examining samples of all kinds including metals, polymers, ceramics, semicon

      Table of Contents

      Preface xiii

      1. Introduction 1

      1.1 X-Ray Technology, a Brief History, 1

      1.2 Geometry of Crystals, 2

      1.3 Principles of X-Ray Diffraction, 11

      1.4 Reciprocal Space and Diffraction, 13

      1.5 Two-Dimensional X-Ray Diffraction, 19

      References, 26

      2. Geometry and Fundamentals 29

      2.1 Introduction, 29

      2.2 Diffraction Space and Laboratory Coordinates, 31

      2.3 Detector Space and Detector Geometry, 35

      2.4 Sample Space and Goniometer Geometry, 46

      2.5 Transformation from Diffraction Space to Sample Space, 50

      2.6 Reciprocal Space, 52

      2.7 Summary, 53

      References, 55

      3. X-Ray Source and Optics 57

      3.2 X-Ray Optics, 63

      References, 85

      4. X-Ray Detectors 87

      4.1 History of X-Ray Detection Technology, 87

      4.2 Point Detectors in Conventional Diffractometers, 89

      4.3 Characteristics of Point Detectors, 92

      4.4 Line Detectors, 100

      4.5 Characteristics of Area Detectors, 107

      4.6 Types of Area Detectors, 119

      References, 137

      5. Goniometer and Sample Stages 141

      5.1 Goniometer and Sample Position, 141

      5.2 Goniometer Accuracy, 145

      5.3 Sample Alignment and Visualization Systems, 149

      5.4 Environment Stages, 151

      References, 155

      6. Data Treatment 157

      6.1 Introduction, 157

      6.2 Non-Uniform Response Correction, 157

      6.3 Spatial Correction, 161

      6.4 Detector Position Accuracy and Calibration, 166

      6.5 Frame Integration, 177

      6.6 Multiple Frame Merge, 186

      6.7 Scanning 2D Pattern, 194

      6.8 Lorentz, Polarization, and Absorption Corrections, 197

      References, 208

      7. Phase Identification 211

      7.1 Introduction, 211

      7.2 Relative Intensity, 212

      7.3 Geometry and Resolution, 216

      7.4 Sampling Statistics, 221

      7.5 Preferred Orientation Effect, 227

      References, 233

      8. Texture Analysis 235

      8.1 Introduction, 235

      8.2 Pole Density and Pole-Figure, 236

      8.3 Fundamental Equations, 238

      8.4 Data Collection Strategy, 242

      8.5 Texture Data Process, 251

      8.6 Orientation Distribution Function, 256

      8.7 Fiber Texture, 261

      8.8 Polymer Texture, 264

      8.9 Other Advantages of XRD2 for Texture, 268

      References, 269

      9. Stress Measurement 271

      9.1 Introduction, 271

      9.2 Principle of X-ray Stress Analysis, 280

      9.3 Theory of Stress Analysis with XRD2, 292

      9.4 Process of Stress Measurement with XRD2, 307

      9.5 Experimental Examples, 325

      A9.1 Calculate Principal Stresses, 349

      A9.2 Calculate the direction cosines for principal stresses (Eigenvectors), 350

      References, 353

      10. Small Angle X-ray Scattering 357

      10.1 Introduction, 357

      10.2 2D SAXS Systems, 361

      10.3 Applications Examples, 367

      10.4 Some Innovations in 2D SAXS, 370

      References, 374

      11. Combinatorial Screening 379

      11.1 Introduction, 379

      11.2 XRD2 Systems for High Throughput Screening, 380

      11.3 Combined Screening with XRD2 and Raman, 390

      Reference, 393

      12. Miscellaneous Applications 395

      12.1 Percent Crystallinity, 395

      12.2 Crystal Size, 402

      12.3 Retained Austenite, 412

      12.4 Crystal Orientation, 414

      12.5 Thin Film Analysis, 418

      Reference, 429

      13. Innovation and Future Development 433

      13.1 Introduction, 433

      13.2 Scanning Line Detector for XRD2, 434

      13.3 Three-Dimensional Detector, 438

      13.4 Pixel Direct Diffraction Analysis, 441

      13.5 High Resolution Two-Dimensional X-Ray Diffractometer, 444

      References, 451

      Appendix A. Values of Commonly Used Parameters 453

      Appendix B. Symbols 459

      Index 465

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