TY - JOUR T1 - Simulation of an anomalous behavior of thermoluminescence glow peak of quartz from Nigeria AU - Olubi, O.e. AU - Oniya, E.O. PY - 2018 DA - November DO - 10.1501/nuclear.2023.26 JF - Journal of Nuclear Sciences PB - Ankara University WT - DergiPark SN - 2147-7736 SP - 50 EP - 57 VL - 4 IS - 2 LA - en AB - Mechanismof the experimentally observed anomalous shift of a thermoluminescence (TL)glow peak that varied with irradiation dose is yet to be fully established. Atheory that the anomalous peak must have contained more than one first ordercomposite peak each with different TL dose characteristics has been one majorexplanation proposed to explain this observation. This work was undertaken tosimulate the anomalous glow peak by using a modified version of a previouslyproposed model and numerically solving sets of simultaneous differentialequations governing the stages of TL phenomena (excitation, relaxation andheating). In the modified model, two additional electron trapping centers wereincorporated in order to simulate accurately this glow curve. Computerized curve deconvolution (CGCD) analyses was carriedout on the simulated glow peak inattempt to retrieve back the electron trapping center energies and to identifytheir respective peak positions. The outcome of this confirmed the peak to bepossibly composite in nature comprising three overlapping glow peaks at 288,300 and 317oC with respective energy gaps of 1.70, 1.73 and 1.75eV. Itis therefore further substantiated that this kind of temperature shift of peakwith dose resulting from composite glow peaks is possible. KW - simulation KW - anomalous glow peak KW - quartz KW - GCD analyses KW - thermoluminesence CR - [1] Adamiec, G., 2005. Properties of the 360 and 550 nm TL Emissions of the ‘110 ◦C Peak’ in Fired Quartz. Radiat. Meas. 39, 105–110. CR - [2] Adamiec, G., Garcia-Talavera, M., Bailey, R.M., La Torre, P.I. de, 2004. Application of a genetic algorithm to finding parameter values for numerical simulation of quartz luminescence. Geochronometria 23, 9–14. CR - [3] Afouxenidis, D., Polymeris, G. S., Tsirliganis, N. C., Kitis, G., 2012. Computerised curve deconvolution of TL/OSL curves using a popular spreadsheet program. Radiation Protection Dosimetry. 149 (4): 363–370. CR - [4] Bailey, R.M., 2001. Towards a general kinetic model for optically and thermally stimulated luminescence in quartz. Radiat. Meas. 33, 17–45. CR - [5] Bailey, R., 2002. Simulations of variability in the luminescence characteristics of natural quartz and its implications for estimates of absorbed dose. Radiation Protection Dosimetry 100, 33–38. CR - [6] Bailey, R., 2004. Paper I - Simulation of dose absorption in quartz over geological timescales and its implications for the precision and accuracy of optical dating. Radiation Measurements 38, 299–310. CR - [7] Basun, S., Imbusch, G.F., Jia, D.D. and Yen, M.W., 2003. The Analysis of Thermoluminescence Glow Curves. Journal of Luminescence. 104, 283-294. CR - [8] Chen, G. and Li, S. H., 2000. Studies of Quartz 110oC Thermoluminescence Peak Sensitivity Change and its Relevance to Optically Stimulated Luminescence Dating. J. Phys. D: Appl. Phys. 33,437–443. CR - [9] Chen, R. and Pagonis, V, 2011. Thermally and Optically Stimulated Luminescence: A Simulation Approach. John Wiley and Sons Ltd, UK. CR - [10] Figel, M. and Geodicke, C. 1999. Simulation of the pre-dose effect of the 100oC TL peak in quartz. Radiation Protection Dosimetry 84, 433-438. CR - [11] Friedrich, J., Kreutzer, S., Schmidt, C., 2016. Solving ordinary differential equations to understand luminescence: ’RLumModel’, an advanced research tool for simulating luminescence in quartz using R. Quaternary Geochronology 35, 88–100. CR - [12] Friedrich, J., Pagonis, V., Chen, R., Kreutzer, S., Schmidt, C., 2017. Quartz radiofluorescence: A modelling approach. Journal of Luminescence 186, 318–325. CR - [13] Horowitz, Y. S. Yossian, D., 1995. Computerized glow curve deconvolution application to thermoluminescence dosimetry. Radiation Protection Dosimetry. Spec. Issue, 60. CR - [14] Kitis G., and Furetta, C., 2006. Simulation of competing irradiation and fading effects in thermoluminescence dosimetry. Radiation Effects and Defects in Solids 160, 285-296. CR - [15] Kitis, G. Gomez-Ros, J. M. Tuyn and J. W. N., 1998. Thermoluminescence glowcurve deconvolution functions for first, second and general orders of kinetics. Journal of Physics D. Applied Physics 31: 2636-2641. CR - [16] Kitis, G., 2001. TL glow-curve deconvoluion functions for various kinetic orders and continuous trap distribution. Acceptance criteria for E and s values. Journal of Radioanalytical and Nuclear Chemistry. 247 (3): 697-703. CR - [17] Koul, D.K., 2008. 110oC Thermoluminescence Glow Peak of Quartz -A Brief Review. Pranama Journal of Physics 71, 1209-1229. CR - [18] Kristianpoller, N., Chen, R., Israel, M., 1974. Dose dependence of thermoluminescence peaks. J. Phys. D: Appl. Phys. 7, 1063–1071. CR - [19] Marcazzo, J., Santiago, M., Spano, F., Lester, M., Ortege, F., Molina, P. and Caselli, E., 2007. Effect of the Interaction among Traps on the shape of Thermoluminescence Glow Curves. Journal of Luminescence. 126, 245-250. CR - [20] Ogundare, F.O. and Chithambo, M.L., 2007. Thermoluminescence Kinetic Analysis of Quartz with a Glow Peak that Shifts in an Unusual Manner with Irradiation Dose. J. Phys. D: Appl. Phys. 40, 247-253. CR - [21] Ogundare, F.O., Chithambo, M.L. and Oniya, E.O., 2006. Anomalous Behaviour of Thermoluminescence from Quartz: A Case of Glow Peaks From a Nigerian Quartz. Radiat. Meas. 41, 549-553. CR - [22] Oniya E. O. (2015). Dependence of heating rates of thermal activation on thermal activation characteristics of 110oC TL peak of quartz: A simulation approach. Radiation Physics and Chemistry. Elsevier Ltd UK. 115 pages 171–178 http://dx.doi.org/10.1016/j.radphyschem.2015.06.020 CR - [23] Oniya, E.O., Polymeris, G.S., Jibiri N. N., Tsirliganis, N.C., Babalola I. A., Kitis, G., (2015). Contributions of pre-exposure dose and thermal activation in pre-dose sensitizations of unfired and annealed quartz. Radiation Physics and Chemistry. Elsevier Ltd UK. 110), pages 105–113 http://dx.doi.org/10.1016/j.radphyschem.2015.01.033 CR - [24] Oniya, E.O., Polymeris, G.S., Tsirliganis, N.C., Kitis, G., 2012. On the Pre-dose Sensitization of the Various Components of the LM-OSL Signal of Annealed Quartz; Comparison with the Case of 110oC TL Peak. Radiat Meas. 47, 864-869. CR - [25] Pagonis, V., Wintle, A.G., Chen, R., 2007. Simulations of the Effect of Pulse Annealing on Optically-Stimulated Luminescence of Quartz. Radiat. Meas. 42, 1587–1599. CR - [26] Pagonis, V., Balsamo, E., Barnold, C., Duling, K., McCole, S., 2008 (b). Simulations of the predose technique for retrospective dosimetry and authenticity testing. Radiation Measurements 43, 1343–1353. CR - [27] Pagonis, V., Wintle, A.G., Chen, R., Wang, X.L., 2008 (a). A Theoretical Model for a New Dating Protocol for Quartz Based on Thermally Transferred OSL (TT-OSL). Radiat. Meas. 43, 704 – 708. CR - [28] Preusser, F., Chithambo, M. L., Götte, T., Martini, M., Ramseyer, K., Sendezera, E. J., Susino, G. J., Wintle, G. J., 2009. Quartz as a Natural Luminescence Dosimeter. Earth-Science Reviews 97, 184–214. CR - [29] Popko, E.A. and Weinstein I.A., 2016. Thermoluminescence curves simulation using genetic algorithm with factorial design. Modern Physics Letters B 30, 1650144 (7 pages). CR - [30] Rasheedy, M.S., Algethami, N.T., 2012. Adaptation of the OTOR-model to explain exactly the thermoluminescence processes during thermal excitation. Physica Scripta, 86, 045703 (7 pages). CR - [31] Rodine, E.T., Land, P.L., 1971. Electronic Defect Structure of Single-crystal ThO2 by Thermoluminescence. Phys. Rev. B 4 (8), 2701–2724. CR - [32] Singh, L. L, Gartia R.K., 2013. Derivation of an expression for lifetime ("τ" ) in OTOR model. Nuclear Instruments and Methods in Physics Research B. 308, 21-23 CR - [33] Singh, L., Kaur, N., Singh, M., 2012. Thermoluminescence Characteristics of High Gamma Dose Irradiated Muscovite Mica. Indian Journal of Pure and Applied Physics 50, 14-18. CR - [34] Subedi, B., Oniya, E., Polymeris, G.S., Afouxenidis, D., Tsirliganis, N. C., Kitis, G., 2011. Thermal quenching of thermoluminescence in quartz samples of various origin. Nuclear Instruments and Methods in Physics Research B. 269, 572–581. CR - [35] Subedi, B., Kitis, G., Pagonis, V., 2010. Simulation of the influence of thermal quenching on thermoluminescence glow-peaks. Phys. Status Solidi A 207, 1216-1226. CR - [36] Wintle, A. G., 1997. Luminescence dating. laboratory procedures and protocols. Radiation Measurements. 27, 769-817. CR - [37] Yazici, A.N., Chen, R., Solak, S., Yegingil, Z., 2002. The Analysis of Thermoluminescence Glow Peaks of CaF2: Dy (TLD-200) after β-Irradiation. J. Phys. D: Appl. Phys. 35, 2526-2535. UR - https://doi.org/10.1501/nuclear.2023.26 L1 - https://dergipark.org.tr/en/download/article-file/572441 ER -