THERMALLY AND OPTICALLY STIMULATED LUMINESCENCE - A SIMULATION APPROACH

The emphasis in the present book will be on results that one can get from simulations, which can add a new dimension to results from theoretical considerations mainly based on simplifying assumptions. Chapter 1 will introduce both techniques. Thermoluminescence, methods for evaluating trapping parameters and additional phenomena of TL will be featured in Chapters 2 to Chapter 4. Optically stimulated luminescence (OSL) will be discussed in Chapter 5 and the n the next chapters will detail analytical and approximate expressions of dose dependence of TL and OSL and simulations of TL and OSL in dating and dosimetry procedures. Chapters 8 and 9 will detail the pre-dose (sensitization) effect and simultaneous measurements. Chapters 10 to 13 will focus on applications in medical physics, radiophotoluminescence, quantum-mechanical basis of TL and OSL and the exponential integral. The book will conclude with the appendix and the bibliography.

Reuven Chen
Professor Reuven Chen is a Professor Emeritus at Tel-Aviv University. He has been working on thermoluminescence, optically stimulated luminescence and other related topics in the last 48 years. Professor Chen has published ~170 scientific papers and two books. He has been a Visiting Professor at several universities in the US, Britain, Canada, Australia, Brazil, France and Hong-Kong. At present, he is an Associate Editor of Radiation Measurements and referee for several international journals.

Vasilis Pagonis
Professor Vasilis Pagonis is a Professor of Physics at McDaniel College. His research involves working on modeling properties of dosimetric materials and their applications in luminescence dating and radiation dosimetry. Professor Pagonis has published ~70 scientific papers, as well as the book Numerical and practical exercises in thermoluminescence, published by Springer in 2006. He currently holds the Kopp endowed chair in the physical sciences at McDaniel College.

PREFACE.

Chapter 1. Introduction.
1.1. The Physical mechanism of TL and OSL phenomena.
1.2. Historical development of TL and OSL dosimetry.
1.3. Historical development of luminescence models.

Chapter 2. Theoretical Basis of Luminescence Phenomena.
2.1. Energy Bands and Energy Levels in Crystals.
2.2. Trapping Parameters Associated with Impurities in Crystals.
2.3. Capture Rate Constants.
2.4. Thermal Equilibrium.
2.5. Detailed Balance.
2.6. Arrhenius Model.
2.7. Rate Equations in the Theory of Luminescence.
2.8. Radiative Emission and Absorption.
2.9. Mechanisms of thermal quenching in dosimetric materials.
2.10. A kinetic model for the Mott-Seitz mechanism in quartz.
2.11. The thermal quenching model for alumina by Nikiforov et al.

Chapter 3. Basic Experimental Measurements.
3.1. General approach to TL and OSL phenomena.
3.2. Excitation spectra.
3.3. Emission spectra.
3.4. Bleaching of thermoluminescence and OSL.

Chapter 4. Thermoluminescence: The Equations Governing a TL Peak.
4.1. Governing equations.
4.2. One trap-one recombination center (OTOR) model.
4.3. General-order kinetics.
4.4. Mixed-order kinetics.
4.5. Q- and P-functionsQ- and P-functions.
4.6. Localized transitions.
4.7. Semilocalized (SLT) models of thermoluminescence.

Chapter 5. Basic Methods for Evaluating Trapping Parameters.
5.1. The initial-rise method.
5.2. Peak-shape methods.
5.3. Methods of various heating rates.
5.4. Curve _tting.
5.5. Developing equations for evaluating glow parameters.
5.6. The photoionization cross section.

Chapter 6. Additional Phenomena associated with TL.
6.1. Phosphorescence decay.
6.2. Isothermal decay of TL peaks.
6.3. Anomalous fading and anomalous trapping parameters of TL.
6.4. Competition between excitation and bleaching of TL.
6.5. A model for mid-term fading in TL dating; continuum of traps.
6.6. Photo-transferred thermoluminescence (PTTL).
6.7. TL-response of Al2O3 : C to UV-illumination.
6.8. Dependence of the TL excitation on absorption coe_cient.
6.9. TL vs. impurity concentration; concentration quenching.
6.10. Creation and stabilization of TL traps during irradiation.
6.11. Duplicitous TL peak due to release of electrons and holes.
6.12. Simulations of the duplicitous TL peak.

Chapter 7. Optically Stimulated Luminescence (OSL).
7.1. Basic concepts of optically stimulated luminescence (OSL).
7.2. Dose dependence of OSL; basic considerations.
7.3. Numerical results of OSL dose dependence.
7.4. Simulation of the dose-rate dependence of OSL.
7.5. The role of retrapping in the dose dependence of pulsed OSL.
7.6. Linear-modulation OSL (LM-OSL).
7.7. Uni_ed presentation of TL, phosphorescence (PL) and LM-OSL.
7.8. The new presentation of LM-OSL within the OTOR model.
7.9. TL-like presentation of CW-OSL in the OTOR model.
7.10. Dependence of luminescence on initial occupancy; OTOR model.
7.11. TL expression within the uni_ed presentation.
7.12. Pseudo LM-OSL and OSL signals under various stimulation modes.
7.13. OSL decay and stretched-exponential behavior.
7.14. Optically stimulated exoelectron emission.
7.15. Simulations of OSL pulsed annealing techniques.

Chapter 8. Analytical and Approximate Expressions of Dose Dependence of TL and OSL.
8.1. General considerations.
8.2. Competition during excitation.
8.3. Competition during heating.
8.4. The predose (sensitization) e_ect.
8.5. Sensitization and de-sensitization in quartz.
8.6. Dose-rate dependence.
8.7. Sublinear dose dependence of TL and LM-OSL in the OTOR system.
8.8. Dose-dependence and dose-rate behaviors by simulations.
8.9. Simulations of the dose-rate e_ect of TL.
8.10. Non-monotonic dose dependence of TL and OSL.
8.11. Non-monotonic dose dependence of TL; simulations.
8.12. Non-monotonic e_ect of OSL; results of simulations.

Chapter 9. Simulations of TL and OSL in Dating Procedures.
9.1. The predose e_ect in quartz.
9.2. Simulation of thermal activation characteristics in quartz.
9.3. The Bailey model for quartz.
9.4. Simulation of the predose dating technique.
9.5. The single aliquot regenerative dose (SAR) technique.
9.6. Thermally transferred OSL (TT-OSL).

Chapter 10. Advanced Methods for Evaluating Trapping Parameters.
10.1. Deconvolution.
10.2. Monte-Carlo Methods.
10.3. Genetic Algorithms.
10.4. Application of di_erential evolution to _tting OSL curves.

Chapter 11. Simultaneous TL and Other Types of Measurements.
11.1. Simultaneous TL and TSC measurements, experimental results.
11.2. Theoretical considerations.
11.3. Numerical analysis of simultaneous TL-TSC measurements.
11.4. Thermoluminescence and Optical Absorption.
11.5. Simultaneous measurements of TL and ESR (EPR).
11.6. Simultaneous Measurements of TL and TSEE.

Chapter 12. Applications in Medical Physics.
12.1. Introduction.
12.2. Applications of luminescence detectors in medical physics.
12.3. Examples of in-vivo dosimetric applications.
12.4. Radioluminescence.

Chapter 13. Radiophotoluminescence.
13.1. Development and use of radiophotoluminescence materials.
13.2. The Simplest RPL Model.

Chapter 14. E_ects of Ionization Density on TL response.
14.1. Modeling TL supralinearity due to heavy charged particles.
14.2. Defect-Interaction Model (DIM).
14.3. The uni_ed interaction model (UNIM).

Chapter 15. The Exponential Integral.
15.1. The integral in TL theory.
15.2. Asymptotic series.
15.3. Other methods.

Previous books and review papers on thermoluminescence, optically stimulated luminescence and applications.
Books.
Review papers.
Bibliography.

Appendix A. Examples.
A.1. Simulation of OSL Experiments Using the OTOR Model.
A.2. Simulation of OSL Experiments Using the IMTS Model.
A.3. Simulation of TL Experiment Using the Bailey Model.

Subject Index.
Author Index.