Forward Recoil Spectrometry Applications to Hydrogen Determination in Solids / by Y. Serruys, J. Tirira, P. Trocellier.

The practical properties of many materials are dominated by surface and near-surface composition and structure. An understanding of how the surface region affects material properties starts with an understanding of the elemental composition of that region. Since the most common contaminants are ligh...

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Bibliographic Details
Main Authors:	Serruys, Y. (Author), Tirira, J. (Author), Trocellier, P. (Author)
Corporate Author:	SpringerLink (Online service)
Format:	eBook
Language:	English
Published:	New York, NY : Springer US : Imprint: Springer, 1996.
Edition:	1st ed. 1996.
Series:	Springer eBook Collection.
Subjects:	Analytical chemistry. Atoms. Physics. Solid state physics. Spectroscopy. Microscopy. Condensed matter. Crystallography. Electronic resources (E-books)
Online Access:	Click to view e-book
Holy Cross Note:	Loaded electronically. Electronic access restricted to members of the Holy Cross Community.

Table of Contents:

1. Introduction
1.1. General Description
1.2. Objectives
1.3. Topics
1.4. Historical Background
1.5. Extension of the ERDA Method in IBA Laboratories Worldwide
1.6. Conclusion
References
2. Basic Physical Processes of Elastic Spectrometry
2.1. Introduction
2.2. Kinematics of Elastic Collision
2.3. Geometric Considerations
2.4. Energy Loss
2.5. Straggling
2.6. Conclusion
References
3. Elastic Scattering: Cross-Section and Multiple Scattering
3.1. Introduction
3.2. Elastic Cross Section
3.3. Multiple Scattering
References
4. Elastic Spectrometry: Fundamental and Practical Aspects
4.1. Introduction
4.2. Fundamentals of Recoil Spectrometry
4.3. Practical Spectrometry of Real Targets
References
5. Conventional Recoil Spectrometry
5.1. Introduction
5.2. Mass—Depth and Recoil-Scattered Ion Ambiguities
5.3. Glancing Geometry
5.4. Transmission Geometry
5.5. Sensitivity
5.6. Mass Resolution
References
6. Time of Flight ERDA
6.1. Introduction
6.2. General Considerations
6.3. Time of Flight Detector
6.4. Electrostatic Mirror Detector
6.5. Efficiency and Resolution
6.6. Data Analysis Procedure
6.7. Conclusion
References
7. Depth Profiling by Means of the ERDA ExB Technique
7.1. Introduction
7.2. Physics and Properties of the ExB Filter
7.3. Practical Considerations
7.4. Adjustments for a 350-keV Helium Beam
7.5. Depth Profiling with a High-Energy (MeV) Beam
7.6. Modified ExB Filter for Heavier Elements
7.7. Conclusion
References
8. Recoil Spectrometry with a ?E-E Telescope
8.1. Introduction
8.2. Experimental Considerations
8.3. Performances
8.4. Examples
8.5. Conclusion
References
9. Coincidence Techniques
9.1. Introduction
9.2. Transmission Geometry and Coincidence Techniques
9.3. Single-Element Analysis with CERDA
9.4. Multiple-Element Analysis with CERDA
9.5. Scattering Recoil Coincidence Spectroscopy
9.6. Elastic Recoil Coincidence Spectroscopy
9.7. Position-Sensitive Detectors for Coincidence ERDA Techniques
9.8. Conclusion
References
10. Instrumental Equipment
10.1. Introduction
10.2. Accelerator and Related Equipment
10.3. Beam Line
10.4. Analysis Chamber
10.5. Detection Devices
10.6. Conclusion
References
11. Numerical Methods for Recoil Spectra Simulation and Data Processing
11.1. Introduction
11.2. Simulation Process: Basic Method
11.3. Alternative Simulation Process: Retrograde Method
11.4. Profile Extraction from Experimental Spectra
11.5. Algorithms and Programs
11.6. Adaptation to Other ERDA Variants
11.7. Conclusion
References
12. Applications of Elastic Recoil Spectrometry to Hydrogen Determination in Solids
12.1. Introduction
12.2. Applications in Polymer Sciences
12.3. Applications to Semiconductor Materials
12.4. Applications to Thin Films
12.5. Study of Interface Reactions
12.6. Other Application Fields
12.7. Study of Hydrogen Behavior under Irradiation
12.8. Conclusion
References
13. Elastic Recoil Spectrometry Using High-Energy Ions for Hydrogen and Light Element Profiling
13.1. Introduction
13.2. General Considerations
13.3. Experimental Arrangement for HI-ERDA
13.4. Detection Capabilities
13.5. Application Examples
13.6. Conclusion
References
14. Ion-Beam Damaging Effects
14.1. Introduction
14.2. Basic Considerations on Ion-Beam Damaging
14.3. Elemental Losses
14.4. Reduction of Radiation Damage
14.5. Choice, Preparation, and Stability of Standard Samples
14.6. Conclusion
References
15. Hydrogen Determination by Nuclear Resonance
15.1. Introduction
15.2. General Considerations
15.3. Hydrogen Profiling by Nuclear Resonance
15.4. Comparison with Elastic Recoil Spectrometry
15.5. Conclusion
References
General Conclusion
Acknowledgments
Appendix A. Basic Data References
Appendix B. Calculation of the Detection Solid Angle
Appendix C. Specific Units, Physical Constants, and Conversion Factors
Appendix D. Recent References
Appendix E. Acronyms.

Forward Recoil Spectrometry Applications to Hydrogen Determination in Solids / by Y. Serruys, J. Tirira, P. Trocellier.

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