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Abstract
Quartz is an omnipresent abundant natural mineral, used for luminescence dating. Lately, quartz optically stimulated luminescence (OSL) technique is widely used to estimate the equivalent doses (De) for dating geological events (up to 250 Gy, limited by saturation). Some works report thermoluminescence (TL) saturation around ~ (10-40) kGy. Still dose estimates for such high radiation dose (HRD) range are not achieved. Significant research exists about luminescence response for low dose ranges (<250 Gy) but limited studies are done for HRDs (>1 kGy). This work characterizes the luminescence response of quartz for HRDs (1-21 kGy) to improve existing understanding of luminescence mechanism. Results show that the characteristics of the trap (<200°C) differ significantly at HRDs than low doses. TL in multi-spectral detection (UV-Visible) band suggest an increase in 340-380°C peak intensity up to 11 kGy dose. The measurements of saturation dose suggest that it depends on the trapping centres but is independent of recombination centres for the samples used for study. The traps are found to be bleachable by sunlight, reducing TL signal to residual levels in 1 hour. Further, the bleachability is found to be anti-correlated with luminescence emission wavelength. At HRDs luminescence sensitivity is influenced by given previous dose which is difficult to correct by routine normalization procedures. The work also explores the normalization method suitable for HRD estimation and recommends the use of mass normalization as other normalization methods do not correct the sensitivity changes at HRDs adequately.
DOI
https://doi.org/10.31223/X5XH67
Subjects
Life Sciences, Physical Sciences and Mathematics
Keywords
Quartz; High dose response; Thermoluminescence; Multispectral; Normalization; Bleachability; previous dose effects
Dates
Published: 2024-05-31 02:50
Last Updated: 2024-05-31 09:50
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