Supplementary material to "Attenuation of beta radiation in granular matrices: implications for trapped-charge dating"

IF 2.7 Q2 GEOCHEMISTRY & GEOPHYSICS Geochronology Pub Date : 2021-06-02 DOI:10.5194/gchron-2021-17-supplement
A. Cunningham, J. Buylaert, A. Murray
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Abstract

Abstract. Mineral grains within sediment or rock absorb a radiation dose from the decay of radionuclides in the host matrix. For the beta dose component, the estimated dose rate must be adjusted for the attenuation of beta particles within the mineral grains. Standard calculations, originally designed for thermoluminescence dating of pottery, assume that the grain is embedded in a homogenous medium. However, most current applications of trapped-charge dating concern sand- or silt-sized dosimeters embedded in granular sediment. In such cases, the radionuclide sources are not homogeneous, but are localized in discrete grains or held on grain surfaces. We show here that the mean dose rate to dosimeter grains in a granular matrix is dependent on the grain-size distributions of the source grains, and of the bulk sediment, as well as on the grain size of the dosimeters. We further argue that U and Th sources are likely to be held primarily on grain surfaces, which causes the dose rate to dosimeter grains to be significantly higher than for sources distributed uniformly throughout grains. For a typical well-sorted medium sand, the beta dose rates derived from surface U and Th sources are higher by 9 % and 14 %, respectively, compared to a homogenous distribution of sources. We account for these effects using an expanded model of beta attenuation, and validate the model against Monte Carlo radiation transport simulations within a geometry of packed spheres.
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“颗粒基质中β辐射的衰减:对俘获电荷定年的影响”的补充材料
摘要沉积物或岩石中的矿物颗粒从宿主基质中的放射性核素衰变中吸收一定剂量的辐射。对于-剂量成分,估计剂量率必须根据-颗粒在矿物颗粒内的衰减进行调整。最初为陶器的热释光测年而设计的标准计算,假定谷物嵌入在一种均匀的介质中。然而,目前大多数捕获电荷测年的应用都涉及嵌入颗粒沉积物中的砂或粉粒大小的剂量计。在这种情况下,放射性核素源不是均匀的,而是局部分布在离散的颗粒中或保持在颗粒表面。我们在这里表明,颗粒基质中剂量计颗粒的平均剂量率取决于源颗粒和大块沉积物的粒度分布,以及剂量计的粒度。我们进一步认为,U和Th源可能主要集中在颗粒表面,这导致剂量计颗粒的剂量率明显高于均匀分布在整个颗粒中的剂量率。对于典型的分级良好的介质砂,与均匀分布的源相比,来自表面U和Th源的β剂量率分别高出9%和14%。我们使用β衰减的扩展模型来解释这些影响,并在填充球体的几何形状中通过蒙特卡罗辐射输运模拟来验证该模型。
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来源期刊
Geochronology
Geochronology Earth and Planetary Sciences-Paleontology
CiteScore
6.60
自引率
0.00%
发文量
35
审稿时长
19 weeks
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