Forward Recoil Spectrometry [electronic resource] : Applications to Hydrogen Determination in Solids /

Forward Recoil Spectrometry [electronic resource] : Applications to Hydrogen Determination in Solids /

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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 light elements (for example, oxygen, nitrogen, carbon, and hydrogen), there is a clear need for an analytic probe that simultaneously and quantitatively records elemental profiles of all light elements. Energy recoil detection using high-energy heavy ions is unique in its ability to provide quantitative profiles of light and medium mass elements. As such this method holds great promise for the study of a variety of problems in a wide range of fields. While energy recoil detection is one of the newest and most promising ion beam analytic techniques, it is also the oldest in terms of when it was first described. Before discussing recent developments in this field, perhaps it is worth reviewing the early days of this century when the first energy recoil detection experiments were reported.

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Bibliographic Details
Main Authors: Tirira, Jorge. author., Serruys, Yves. author., Trocellier, Patrick. author., SpringerLink (Online service)
Format: Texto biblioteca
Language:eng
Published: Boston, MA : Springer US, 1996
Subjects:Chemistry., Analytical chemistry., Atoms., Physics., Condensed matter., Solid state physics., Crystallography., Spectroscopy., Microscopy., Analytical Chemistry., Atomic, Molecular, Optical and Plasma Physics., Solid State Physics., Spectroscopy and Microscopy., Condensed Matter Physics.,
Online Access:http://dx.doi.org/10.1007/978-1-4613-0353-4
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id KOHA-OAI-TEST:175649
record_format koha
institution COLPOS
collection Koha
country México
countrycode MX
component Bibliográfico
access En linea
En linea
databasecode cat-colpos
tag biblioteca
region America del Norte
libraryname Departamento de documentación y biblioteca de COLPOS
language eng
topic Chemistry.
Analytical chemistry.
Atoms.
Physics.
Condensed matter.
Solid state physics.
Crystallography.
Spectroscopy.
Microscopy.
Chemistry.
Analytical Chemistry.
Atomic, Molecular, Optical and Plasma Physics.
Solid State Physics.
Spectroscopy and Microscopy.
Condensed Matter Physics.
Crystallography.
Chemistry.
Analytical chemistry.
Atoms.
Physics.
Condensed matter.
Solid state physics.
Crystallography.
Spectroscopy.
Microscopy.
Chemistry.
Analytical Chemistry.
Atomic, Molecular, Optical and Plasma Physics.
Solid State Physics.
Spectroscopy and Microscopy.
Condensed Matter Physics.
Crystallography.
spellingShingle Chemistry.
Analytical chemistry.
Atoms.
Physics.
Condensed matter.
Solid state physics.
Crystallography.
Spectroscopy.
Microscopy.
Chemistry.
Analytical Chemistry.
Atomic, Molecular, Optical and Plasma Physics.
Solid State Physics.
Spectroscopy and Microscopy.
Condensed Matter Physics.
Crystallography.
Chemistry.
Analytical chemistry.
Atoms.
Physics.
Condensed matter.
Solid state physics.
Crystallography.
Spectroscopy.
Microscopy.
Chemistry.
Analytical Chemistry.
Atomic, Molecular, Optical and Plasma Physics.
Solid State Physics.
Spectroscopy and Microscopy.
Condensed Matter Physics.
Crystallography.
Tirira, Jorge. author.
Serruys, Yves. author.
Trocellier, Patrick. author.
SpringerLink (Online service)
Forward Recoil Spectrometry [electronic resource] : Applications to Hydrogen Determination in Solids /
description 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 light elements (for example, oxygen, nitrogen, carbon, and hydrogen), there is a clear need for an analytic probe that simultaneously and quantitatively records elemental profiles of all light elements. Energy recoil detection using high-energy heavy ions is unique in its ability to provide quantitative profiles of light and medium mass elements. As such this method holds great promise for the study of a variety of problems in a wide range of fields. While energy recoil detection is one of the newest and most promising ion beam analytic techniques, it is also the oldest in terms of when it was first described. Before discussing recent developments in this field, perhaps it is worth reviewing the early days of this century when the first energy recoil detection experiments were reported.
format Texto
topic_facet Chemistry.
Analytical chemistry.
Atoms.
Physics.
Condensed matter.
Solid state physics.
Crystallography.
Spectroscopy.
Microscopy.
Chemistry.
Analytical Chemistry.
Atomic, Molecular, Optical and Plasma Physics.
Solid State Physics.
Spectroscopy and Microscopy.
Condensed Matter Physics.
Crystallography.
author Tirira, Jorge. author.
Serruys, Yves. author.
Trocellier, Patrick. author.
SpringerLink (Online service)
author_facet Tirira, Jorge. author.
Serruys, Yves. author.
Trocellier, Patrick. author.
SpringerLink (Online service)
author_sort Tirira, Jorge. author.
title Forward Recoil Spectrometry [electronic resource] : Applications to Hydrogen Determination in Solids /
title_short Forward Recoil Spectrometry [electronic resource] : Applications to Hydrogen Determination in Solids /
title_full Forward Recoil Spectrometry [electronic resource] : Applications to Hydrogen Determination in Solids /
title_fullStr Forward Recoil Spectrometry [electronic resource] : Applications to Hydrogen Determination in Solids /
title_full_unstemmed Forward Recoil Spectrometry [electronic resource] : Applications to Hydrogen Determination in Solids /
title_sort forward recoil spectrometry [electronic resource] : applications to hydrogen determination in solids /
publisher Boston, MA : Springer US,
publishDate 1996
url http://dx.doi.org/10.1007/978-1-4613-0353-4
work_keys_str_mv AT tirirajorgeauthor forwardrecoilspectrometryelectronicresourceapplicationstohydrogendeterminationinsolids
AT serruysyvesauthor forwardrecoilspectrometryelectronicresourceapplicationstohydrogendeterminationinsolids
AT trocellierpatrickauthor forwardrecoilspectrometryelectronicresourceapplicationstohydrogendeterminationinsolids
AT springerlinkonlineservice forwardrecoilspectrometryelectronicresourceapplicationstohydrogendeterminationinsolids
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spelling KOHA-OAI-TEST:1756492018-07-30T22:54:10ZForward Recoil Spectrometry [electronic resource] : Applications to Hydrogen Determination in Solids / Tirira, Jorge. author. Serruys, Yves. author. Trocellier, Patrick. author. SpringerLink (Online service) textBoston, MA : Springer US,1996.engThe 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 light elements (for example, oxygen, nitrogen, carbon, and hydrogen), there is a clear need for an analytic probe that simultaneously and quantitatively records elemental profiles of all light elements. Energy recoil detection using high-energy heavy ions is unique in its ability to provide quantitative profiles of light and medium mass elements. As such this method holds great promise for the study of a variety of problems in a wide range of fields. While energy recoil detection is one of the newest and most promising ion beam analytic techniques, it is also the oldest in terms of when it was first described. Before discussing recent developments in this field, perhaps it is worth reviewing the early days of this century when the first energy recoil detection experiments were reported.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.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 light elements (for example, oxygen, nitrogen, carbon, and hydrogen), there is a clear need for an analytic probe that simultaneously and quantitatively records elemental profiles of all light elements. Energy recoil detection using high-energy heavy ions is unique in its ability to provide quantitative profiles of light and medium mass elements. As such this method holds great promise for the study of a variety of problems in a wide range of fields. While energy recoil detection is one of the newest and most promising ion beam analytic techniques, it is also the oldest in terms of when it was first described. Before discussing recent developments in this field, perhaps it is worth reviewing the early days of this century when the first energy recoil detection experiments were reported.Chemistry.Analytical chemistry.Atoms.Physics.Condensed matter.Solid state physics.Crystallography.Spectroscopy.Microscopy.Chemistry.Analytical Chemistry.Atomic, Molecular, Optical and Plasma Physics.Solid State Physics.Spectroscopy and Microscopy.Condensed Matter Physics.Crystallography.Springer eBookshttp://dx.doi.org/10.1007/978-1-4613-0353-4URN:ISBN:9781461303534

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