Research ArticleNo Access

A Pedagogical Numerical Simulation of Persistent Luminescence Phenomenon for Teaching Radiation Dosimetry

Dirección de Lenguas Extranjeras, Posgrado e Investigación, Universidad Kino A.C., Hermosillo, Sonora C.P. 83079, México

E-mail Address: chjsalasjuarez@gmail.com

Corresponding author.

Search for more papers by this author

S. E. Burruel-Ibarra

Departamento de Investigación en Polímeros y Materiales, Universidad de Sonora, Hermosillo, Sonora C.P. 83000, México

Search for more papers by this author

C. E. Gómez-Dominguez

Dirección de Lenguas Extranjeras, Posgrado e Investigación, Universidad Kino A.C., Hermosillo, Sonora C.P. 83079, México

Search for more papers by this author

M. Martínez-Gil

Centro de Nanociencias y Nanotecnología, Universidad Nacional Autónoma de México, Ensenada, Baja California C.P. 22800, México

Search for more papers by this author

, and

H. A. Borbón-Nuñez

Centro de Nanociencias y Nanotecnología, Universidad Nacional Autónoma de México, Ensenada, Baja California C.P. 22800, México

Search for more papers by this author

https://doi.org/10.1142/S2661339522500135Cited by:0 (Source: Crossref)

Abstract

This paper presents the theoretical bases and numerical simulation of the persistent luminescence applied to radiation dosimetry to create an educational exercise for undergraduate students who are beginning in the areas of physics and radiation dosimetry. Numerical simulation of persistent luminescence curves was performed using Mathcad v15 software. Persistent luminescence curves with first-order kinetics were simulated, and their relationship with the thermoluminescence phenomenon was also studied. In addition, this paper explains a series of numerical simulations that include various types of experiments that can be carried out to characterize materials that are constituted by a persistent luminescence property, for instance, dose-response, reusability, selection of measurement temperature, determination of lifetime $τ$ , energy activation E, and frequency factor s.

Keywords:

References

1. J. Xu and S. Tanabe , Persistent luminescence instead of phosphorescence: History, mechanism, and perspective, J. Lumin. 205, 581–620 (2019). Crossref, Google Scholar
2. C. Salas-Juárez, C. Cruz-Vázquez, R. Avilés-Monreal and R. Bernal , Afterglow based detection and dosimetry of beta particle irradiated ZrO₂, Appl. Radiat. Isot. (2017), https://doi.org/10.1016/j.apradiso.2017.10.026. Google Scholar
3. H. Tan, T. Wang, Y. Shao, C. Yu and L. Hu , Crucial breakthrough of functional persistent luminescence materials for biomedical and information technological applications, Front. Chem. 7 (2019), https://doi.org/10.3389/fchem.2019.00387. Crossref, Google Scholar
4. P. Sengar, H. A. Borbón-Nuñez, C. J. Salas-Juárez, E. M. Aguilar, C. Cruz-Vázquez, R. Bernal and G. A. Hirata , $β$ -Irradiated thermoluminescence response of nanocrystalline YAGG:Pr $^{3 +}$ for radiation dosimetry, Mater. Res. Bull. 90 (2017), https://doi.org/10.1016/j.materresbull.2017.03.001. Crossref, Google Scholar
5. T. C. Hernández-Pérez, R. Bernal, C. Cruz-Vázquez, F. Brown, A. Mendoza-Córdova, C. J. Salas-Juárez and R. Avilés-Monreal, Afterglow dosimetry performance of beta particle irradiated lithium zirconate (n.d.), https://doi.org/10.1016/ j.apradiso.2017.10.027. Google Scholar
6. H. F. Brito, J. Hölsä, T. Laamanen, M. Lastusaari, M. Malkamäki and L. C. V. Rodrigues , Persistent luminescence mechanisms: Human imagination at work, Opt. Mater. Express. 2, 371 (2012). Crossref, Google Scholar
7. K. Van den Eeckhout, P. F. Smet and D. Poelman , Persistent luminescence in Eu2+-doped compounds: A review, Materials (Basel), 3, 2536–2566 (2010). Crossref, Google Scholar
8. R. Gao, M. S. Kodaimati and D. Yan , Recent advances in persistent luminescence based on molecular hybrid materials, Chem. Soc. Rev. 50, 5564–5589 (2021). Crossref, Google Scholar
9. J. Du, O. Q. De Clercq and D. Poelman , Temperature dependent persistent luminescence: Evaluating the optimum working temperature, Sci. Rep. 9, 1–11 (2019). Crossref, Google Scholar
10. V. Castaing, E. Arroyo, A. I. Becerro, M. Ocaña, G. Lozano and H. Míguez , Persistent luminescent nanoparticles: Challenges and opportunities for a shimmering future, J. Appl. Phys. 130 (2021), https://doi.org/10.1063/5.0053283. Crossref, Google Scholar
11. N. Liu, X. Chen, X. Sun, X. Sun and J. Shi , Persistent luminescence nanoparticles for cancer theranostics application, J. Nanobiotechnology 19, 1–24 (2021). Google Scholar
12. S. K. Omanwar, K. A. Koparkar and H. S. Virk , Recent advances and opportunities in tld materials: A review, Defect Diffus. Forum. 347, 75–110 (2014). Crossref, Google Scholar
13. K. V. R. Murthy , Thermoluminescence and its applications: A review, Defect Diffus. Forum. 347, 35–73 (2014). Crossref, Google Scholar
14. V. Kortov , Materials for thermoluminescent dosimetry: Current status and future trends, Radiat. Meas. 42, 576–581 (2007). Crossref, Google Scholar
15. A. J. J. Bos , Theory of thermoluminescence, Radiat. Meas. 41, 45–56 (2006). Crossref, Google Scholar
16. T. Kron, Thermoluminescence dosimetry and its applications in medicine — Part 1: Physics, materials and equipment (2016). Google Scholar
17. P. J. Yadav, C. P. Joshi and S. V. Moharil , Persistent luminescence in Ca 8Zn(SiO 4) 4Cl 2:Eu 2+, J. Lumin. 132, 2799–2801 (2012). Crossref, Google Scholar
18. R. K. Gartia and N. Chandrasekhar , Thermoluminescence of persistent luminescent materials, Defect Diffus. Forum. 357, 171–191 (2014). Crossref, Google Scholar
19. O. Q. De Clercq, J. Du, P. F. Smet, J. J. Joos and D. Poelman , Predicting the after glow duration in persistent phosphors: A validated approach to derive trap depth distributions, Phys. Chem. Chem. Phys. 20, 30455–30465 (2018). Crossref, Google Scholar
20. R. Pérez Salas, R. Meléndrez, R. Aceves and M. Barboza-Flores , Nonthermoluminescent dosimetry based on the afterglow response of europium-doped alkali halides, Appl. Phys. Lett. 63, 3017–3019 (1993). Crossref, Google Scholar
21. M. C. Aznar, C. E. Andersen, L. Bøtter-Jensen, S. Å. Bäck, S. Mattsson, F. Kjær-Kristoffersen and J. Medin , Real-time optical-fibre luminescence dosimetry for radiotherapy: Physical characteristics and applications in photon beams, Phys. Med. Biol. 49, 1655–1669 (2004). Crossref, Google Scholar
22. M. Hernández-Ortiz, L. S. Acosta-Torres, R. Bernal, C. Cruz-Vázquez and V. M. Castãno , Study of afterglow and thermoluminescence properties of synthetic opal-C nanoparticles for in vivo dosimetry applications, Mater. Res. Soc. Symp. Proc. 1530, 35–40 (2013). Crossref, Google Scholar
23. J. A. Montes-Gutiérrez, J. J. Alcantar-Peña, E. de Obaldia, N. J. Zúñiga-Rivera, V. Chernov, R. Meléndrez-Amavizca, M. Barboza-Flores, R. Garcia-Gutierrez and O. Auciello , Afterglow, thermoluminescence and optically stimulated luminescence characterization of micro-, nano- and ultrananocrystalline diamond films grown on silicon by HFCVD, Diam. Relat. Mater. 85, 117–124 (2018). Crossref, Google Scholar
24. K. Santacruz-Gomez, R. Meléndrez, M. I. Gil-Tolano, J. A. Jimenez, M. T. Makale, M. Barboza-Flores, B. Castaneda, D. Soto-Puebla, M. Pedroza-Montero, J. McKittrick and G. A. Hirata , Thermally stimulated luminescence and persistent luminescence of $β$ -irradiated YAG:Pr3+ nanophosphors produced by combustion synthesis, Radiat. Meas. 94, 35–40 (2016). Crossref, Google Scholar
25. M. I. Gil-Tolano, R. Meléndrez, J. C. Lancheros-Olmos, B. Castaneda, D. Soto-Puebla, V. Chernov, M. Pedroza-Montero and M. Barboza-Flores , AG, TL, and IRSL dosimetric properties in X-ray irradiated HPHT diamond crystals, Phys. Status Solidi Appl. Mater. Sci. 211, 2359–2362 (2014). Crossref, Google Scholar
26. V. Chernov, R. Meléndrez, S. Gastélum, M. Pedroza-Montero, T. Piters, S. Preciado-Flores and M. Barboza-Flores , Afterglow and thermoluminescence properties in HPHT diamond crystals under beta irradiation, Phys. Status Solidi Appl. Mater. Sci. 210, 2088–2094 (2013). Crossref, Google Scholar
27. C. Pereyda-Pierre, R. Meléndrez, R. García, M. Pedroza-Montero and M. Barboza-Flores , Persistent luminescence and thermoluminescence of UV/VIS-irradiated SrAl2O4: Eu $^{2 +}$ , Dy $^{3 +}$ phosphor, Radiat. Meas. 46, 1417–1420 (2011). Crossref, Google Scholar
28. O. Arellano-Tánori, R. Meléndrez, M. Pedroza-Montero, B. Castañeda, V. Chernov, W. M. Yen and M. Barboza-Flores , Persistent luminescence dosimetric properties of UV-irradiated SrAl2O4:Eu $^{2 +}$ , Dy $^{3 +}$ phosphor, J. Lumin. 128, 173–184 (2008). Crossref, Google Scholar
29. M. Barboza-Flores, M. Schreck, S. Preciado-Flores, R. Meléndrez, M. Pedroza-Montero and V. Chernov , Afterglow and thermally stimulated luminescence induced by UV radiation in CVD diamond, Phys. Status Solidi Appl. Mater. Sci. 204, 3047–3052 (2007). Crossref, Google Scholar
30. V. Chernov, T. M. Piters, R. Meléndrez, W. M. Yen, E. Cruz-Zaragoza and M. Barboza-Flores , Photoluminescence, afterglow and thermoluminescence in SrAl2O4: Eu2+, Dy3+ irradiated with blue and UV light, Radiat. Meas. 42, 668–671 (2007). Crossref, Google Scholar
31. J. T. Randall and M. H. F. Wilkins , Phosphorescence and electron traps — I. The study of trap distributions, Proc. R. Soc. London. Ser. A. Math. Phys. Sci. 184, 365–389 (1945). Google Scholar
32. A. J. J. Bos , Thermoluminescence as a research tool to investigate luminescence mechanisms, Materials (Basel) 10 (2017), Crossref, Google Scholar
33. C. Furetta and G. Kitis , Models in thermoluminescence, J. Mater. Sci. 39, 2277–2294 (2004). Crossref, Google Scholar
34. K. S. Chung, H. S. Choe, J. I. Lee and J. L. Kim , A new method for the numerical analysis of thermoluminescence glow curve, Radiat. Meas. 42, 731–734 (2007). Crossref, Google Scholar
35. T. Rivera , Thermoluminescence in medical dosimetry, Appl. Radiat. Isot. 71, 30–34 (2012). Crossref, Google Scholar
36. J. L. Lawless, R. Chen and V. Pagonis , Sublinear dose dependence of thermoluminescence and optically stimulated luminescence prior to the approach to saturation level, Radiat. Meas. 44, 606–610 (2009). Crossref, Google Scholar
37. V. Pagonis, G. Kitis and C. Furetta, Numerical and practical exercises in thermoluminescence, (2006), https://doi.org/10.1007/0-387-30090-2. Google Scholar