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Zone Refining of Ultrahigh-Purity Sodium Iodide for Low-Background Detectors
Physical Review Applied ( IF 3.8 ) Pub Date : 2021-07-26 , DOI: 10.1103/physrevapplied.16.014060 Burkhant Suerfu 1 , Frank Calaprice 2 , Michael Souza 2, 3
Physical Review Applied ( IF 3.8 ) Pub Date : 2021-07-26 , DOI: 10.1103/physrevapplied.16.014060 Burkhant Suerfu 1 , Frank Calaprice 2 , Michael Souza 2, 3
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There has been a growing interest in ultrahigh-purity low-background () crystals for dark-matter direct searches. Past research indicates that zone refining is an efficient and scalable way to purify . In particular, and —two elements with radioisotopes that can cause scintillation backgrounds—can be efficiently removed by zone refining. However, zone refining has never been demonstrated for ultrahigh-purity , which has become commercially available recently. In this paper, we show that many common metallic impurities can be efficiently removed via zone refining. A numerical model for predicting the final impurity distribution is developed and used to fit the inductively coupled plasma mass spectrometry (ICPMS) measurement data to determine the segregation coefficient and the initial concentration. Under this scheme, the segregation coefficient for is estimated to be , indicating that zone refining is still effective in removing from ultrahigh-purity . As zone refining tends to move the impurities to one end, elements with concentrations too low to be measured directly in the unprocessed powder can potentially be detected in the end due to the enrichment. We also present an analysis technique to estimate the initial concentrations of impurities with partial data, which effectively enhances the sensitivity of the spectrometer. Using this technique, the initial concentration of is estimated to be between 5 parts per trillion (ppt) and 14 ppt at the 90% confidence level (CL), at least 14 times lower than the detection limit of ICPMS and 7 times lower than the current most stringent limit set by the DAMA collaboration by direct counting of radioactive . These results imply that zone refining is a key technique in developing next-generation -based crystal scintillators for dark-matter direct detection.
中文翻译:
用于低本底探测器的超高纯碘化钠的区域精炼
人们对超高纯低本底越来越感兴趣 () 用于暗物质直接搜索的晶体。过去的研究表明,区域精炼是一种有效且可扩展的净化方式. 特别是, 和 — 两种具有可导致闪烁背景的放射性同位素的元素 — 可以通过区域精炼有效去除。然而,区域精炼从未被证明用于超高纯,最近已经上市。在本文中,我们表明可以通过区域精炼有效去除许多常见的金属杂质。开发了用于预测最终杂质分布的数值模型,并用于拟合电感耦合等离子体质谱 (ICPMS) 测量数据,以确定分离系数和初始浓度。在该方案下,分离系数为 估计是 , 表明区域细化仍然有效去除 从超高纯 . 由于区域精炼倾向于将杂质移动到一端,因此由于富集,最终可能会检测到浓度太低而无法在未加工粉末中直接测量的元素。我们还提出了一种分析技术,用部分数据估计杂质的初始浓度,有效地提高了光谱仪的灵敏度。使用这种技术,初始浓度 在 90% 置信水平 (CL) 下,估计在万亿分之 5 (ppt) 和 14 ppt 之间,至少比 ICPMS 的检测限低 14 倍,比 DAMA 设定的当前最严格的限值低 7 倍通过直接计数放射性进行协作 . 这些结果意味着区域细化是开发下一代的关键技术用于暗物质直接检测的基于晶体闪烁体。
更新日期:2021-07-26
中文翻译:
用于低本底探测器的超高纯碘化钠的区域精炼
人们对超高纯低本底越来越感兴趣 () 用于暗物质直接搜索的晶体。过去的研究表明,区域精炼是一种有效且可扩展的净化方式. 特别是, 和 — 两种具有可导致闪烁背景的放射性同位素的元素 — 可以通过区域精炼有效去除。然而,区域精炼从未被证明用于超高纯,最近已经上市。在本文中,我们表明可以通过区域精炼有效去除许多常见的金属杂质。开发了用于预测最终杂质分布的数值模型,并用于拟合电感耦合等离子体质谱 (ICPMS) 测量数据,以确定分离系数和初始浓度。在该方案下,分离系数为 估计是 , 表明区域细化仍然有效去除 从超高纯 . 由于区域精炼倾向于将杂质移动到一端,因此由于富集,最终可能会检测到浓度太低而无法在未加工粉末中直接测量的元素。我们还提出了一种分析技术,用部分数据估计杂质的初始浓度,有效地提高了光谱仪的灵敏度。使用这种技术,初始浓度 在 90% 置信水平 (CL) 下,估计在万亿分之 5 (ppt) 和 14 ppt 之间,至少比 ICPMS 的检测限低 14 倍,比 DAMA 设定的当前最严格的限值低 7 倍通过直接计数放射性进行协作 . 这些结果意味着区域细化是开发下一代的关键技术用于暗物质直接检测的基于晶体闪烁体。
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