Course in Luminescence Measurements and Analyses for Radiation - Dosimetr

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Informationen zum Autor Stephen W.S. McKeever is an Emeritus Regents Professor in the Department of Physics at Oklahoma State University in the United States. He has published over 200 peer-reviewed papers in the field of luminescence measurements for radiation dosimetry. Klappentext A Course in Luminescence Measurements and Analyses for Radiation Dosimetry A complete approach to the three key techniques in luminescence dosimetry In A Course in Luminescence Measurements and Analyses for Radiation Dosimetry, expert researcher Stephen McKeever delivers a holistic and comprehensive exploration of the three main luminescence techniques used in radiation dosimetry: thermoluminescence, optically stimulated luminescence, and radiophotoluminescence. The author demonstrates how the three techniques are related to one another and how they compare to each other. Throughout, the author's focus is on pedagogy, including state-of-the-art research only where it is relevant to demonstrate a key principle or where it reveals a critical insight into physical mechanisms. The primary purpose of the book is to teach beginning researchers about the three aforementioned techniques, their similarities and distinctions, and their applications. A Course in Luminescence Measurements and Analyses for Radiation Dosimetry offers access to a companion website that includes original data sets and problems to be solved by the reader. The book also includes: A thorough introduction to the field of luminescence applications in radiation dosimetry, including a history of the subject. Comprehensive explorations of introductory models and kinetics, including the concepts of thermoluminescence, optically stimulated luminescence, and radiophotoluminescence. Practical discussions of luminescence curve shapes, including the determination of trapping parameters from experimental thermoluminescence and optically stimulated luminescence data. In-depth examinations of dose-response functions, superlinearity, supralinearity, and sublinearity, as well as the causes of non-linearity. Detailed examples with well-known materials. A Course in Luminescence Measurements and Analyses for Radiation Dosimetry is an invaluable guide for undergraduate and graduate students in the field of radiation dosimetry, as well as faculty and professionals in the field. Zusammenfassung A Course in Luminescence Measurements and Analyses for Radiation DosimetryA complete approach to the three key techniques in luminescence dosimetryIn A Course in Luminescence Measurements and Analyses for Radiation Dosimetry, expert researcher Stephen McKeever delivers a holistic and comprehensive exploration of the three main luminescence techniques used in radiation dosimetry: thermoluminescence, optically stimulated luminescence, and radiophotoluminescence. The author demonstrates how the three techniques are related to one another and how they compare to each other.Throughout, the author's focus is on pedagogy, including state-of-the-art research only where it is relevant to demonstrate a key principle or where it reveals a critical insight into physical mechanisms. The primary purpose of the book is to teach beginning researchers about the three aforementioned techniques, their similarities and distinctions, and their applications.A Course in Luminescence Measurements and Analyses for Radiation Dosimetry offers access to a companion website that includes original data sets and problems to be solved by the reader. The book also includes:* A thorough introduction to the field of luminescence applications in radiation dosimetry, including a history of the subject.* Comprehensive explorations of introductory models and kinetics, including the concepts of thermoluminescence, optically stimulated luminescence, and radiophotoluminescence.* Practical discussions of luminescence curve shapes, including the determi...

List of contents

Preface xiii
 
Acknowledgments xvii
 
Disclaimer xviii
 
About the Companion Website xix
 
Part I Theory, Models, and Simulations 1
 
1 Introduction 3
 
1.1 How Did We Get Here? 3
 
1.2 Introductory Concepts for TL, OSL, and RPL 7
 
1.2.1 Equilibrium and Metastable States 7
 
1.2.2 Fermi-Dirac Statistics 8
 
1.2.3 Related Processes 10
 
1.3 Brief Overview of Modern Applications in Radiation Dosimetry 12
 
1.3.1 Personal Dosimetry 13
 
1.3.2 Medical Dosimetry 14
 
1.3.3 Space Dosimetry 15
 
1.3.4 Retrospective Dosimetry 16
 
1.3.5 Environmental Dosimetry 18
 
1.4 Bibliography of Luminescence Dosimetry Applications 18
 
2 Defects and Their Relation to Luminescence 19
 
2.1 Defects in Solids 19
 
2.1.1 Point Defects 19
 
2.1.2 Extended Defects 23
 
2.1.3 Non-Crystalline Materials 23
 
2.2 Trapping, Detrapping, and Recombination Processes 24
 
2.2.1 Excitation Probabilities 24
 
2.2.1.1 Thermal Excitation 24
 
2.2.1.2 Optical Excitation 28
 
2.2.2 Trapping and Recombination Processes 31
 
3 TL and OSL: Models and Kinetics 35
 
3.1 Rate Equations: OTOR Model 35
 
3.2 Analytical Solutions: TL Equations 38
 
3.2.1 First-Order Kinetics 38
 
3.2.2 Second-Order and General-Order Kinetics 41
 
3.2.3 Mixed-Order Kinetics 46
 
3.3 Analytical Solutions: OSL Equations 49
 
3.3.1 First-Order Kinetics 51
 
3.3.1.1 Expressions for CW-OSL 51
 
3.3.1.2 Expressions for LM-OSL 51
 
3.3.1.3 Expressions for POSL 52
 
3.3.1.4 Expressions for VE-OSL 54
 
3.3.2 Non-First-Order Kinetics 57
 
3.4 More Complex Models: Interactive Kinetics 57
 
3.4.1 Thermoluminescence 57
 
3.4.2 Optically Stimulated Luminescence 65
 
3.5 Trap Distributions 68
 
3.6 Quasi-Equilibrium (QE) 75
 
3.6.1 Numerical Solutions: No QE Assumption 75
 
3.6.2 P and Q Analysis 75
 
3.6.3 Analytical Solutions: No QE Assumption 78
 
3.7 Thermal and Optical Effects 81
 
3.7.1 Thermal Quenching 82
 
3.7.1.1 Mott-Seitz Model 82
 
3.7.1.2 Schön-Klasens Model 85
 
3.7.1.3 Tests for Thermal Quenching 87
 
3.7.2 Thermal Effects on OSL 89
 
3.7.2.1 Effects of Shallow Traps 89
 
3.7.2.2 Effects of Deep Traps: Thermally Transferred OSL (TT-OSL) 91
 
3.7.3 More Temperature Effects for TL and OSL 92
 
3.7.3.1 Phonon-coupling 93
 
3.7.3.2 Shallow Traps 93
 
3.7.3.3 Sub-Conduction Band Excitation 93
 
3.7.3.4 Random Local Potential Fluctuations (RLPF) 95
 
3.7.4 Optical Effects on TL 96
 
3.7.4.1 Bleaching 96
 
3.7.4.2 Phototransferred TL (PTTL) 101
 
3.8 Tunneling, Localized and Semi-Localized Transitions 104
 
3.8.1 Tunneling 106
 
3.8.1.1 General Considerations 106
 
3.8.1.2 Ground-State Tunneling 107
 
3.8.1.3 Excited-State Tunneling 110
 
3.8.1.4 Decay during Irradiation 113
 
3.8.1.5 Effect of Tunneling on TL and OSL 113
 
3.8.2 Localized and Semi-localized Transition Models 115
 
3.8.2.1 Localized Transition Model 115
 
3.8.2.2 Semi-Localized Transition Model 116
 
3.8.2.3 Semi-Localized Transitions and the TL Glow Curve 122
 
3.9 Master Equations 123
 
4 RPL: Models and Kinetics 125
 
4.1 Radiophotoluminescence and Its Differences with TL and OSL 125
 
4.2 Background Considerations 125
 
4.3 Buildup Kinetics 128
 
4.3.1