Technical note: Studying lithium metaborate fluxes and extraction protocols with a new, fully automated in situ cosmogenic ¹⁴C processing system at PRIME Lab

IF 2.7 Q2 GEOCHEMISTRY & GEOPHYSICS

Geochronology Pub Date : 2023-09-20 DOI:10.5194/gchron-5-361-2023

Nathaniel Lifton, Jim Wilson, Allie Koester

{"title":"Technical note: Studying lithium metaborate fluxes and extraction protocols with a new, fully automated in situ cosmogenic <sup>14</sup>C processing system at PRIME Lab","authors":"Nathaniel Lifton, Jim Wilson, Allie Koester","doi":"10.5194/gchron-5-361-2023","DOIUrl":null,"url":null,"abstract":"Abstract. Extraction procedures for in situ cosmogenic 14C (in situ 14C) from quartz require quantitative isotopic yields while maintaining scrupulous isolation from atmospheric and organic 14C. These time- and labor-intensive procedures are ripe for automation; unfortunately, our original automated in situ 14C extraction and purification systems, reconfigured and retrofitted from our original systems at the University of Arizona, proved less reliable than hoped. We therefore installed a fully automated stainless-steel system (except for specific borosilicate glass or fused-silica components) incorporating more reliable valves and improved actuator designs, along with a more robust liquid nitrogen distribution system. As with earlier versions, the new system uses a degassed lithium metaborate (LiBO2) flux to dissolve the quartz sample in an ultra-high-purity oxygen atmosphere, after a lower-temperature combustion step to remove atmospheric and organic 14C. We compared single-use high-purity Al2O3 against reusable 90 %Pt / 10 %Rh (Pt/Rh) sample combustion boats. The Pt/Rh boats heat more evenly than the Al2O3, reducing procedural blank levels and variability for a given LiBO2 flux. This lower blank variability also allowed us to trace progressively increasing blanks to specific batches of fluxes from our original manufacturer. Switching to a new manufacturer returned our blanks to consistently low levels on the order of (3.4 ± 0.9) × 104 14C atoms. We also analyzed the CRONUS-A intercomparison material to investigate sensitivity of extracted 14C concentrations to the temperature and duration of the combustion and extraction steps. Results indicate that 1 h combustion steps at either 500 or 600 ∘C yield results consistent with the consensus value of Jull et al. (2015), while 2 h at 600 ∘C results in loss of ca. 9 % of the high-temperature 14C inventory. Results for 3 h extractions at temperatures ranging from 1050 to 1120 ∘C and 4.5 h at 1000 ∘C yielded similar results that agreed with the nominal value and published results from most laboratories. On the other hand, an extraction for 3 h at 1000 ∘C was judged to be incomplete due to a significantly lower measured concentration. Based on these results, our preferred technique is now combustion for 1 h at 500 ∘C followed by a 3 h extraction at 1050 ∘C. Initial analyses of the CoQtz-N intercomparison material at our lab yielded concentrations ca. 60 % lower than those of CRONUS-A, but more analyses of this material from this and other labs are clearly needed to establish a consensus value.","PeriodicalId":12723,"journal":{"name":"Geochronology","volume":"159 1","pages":"0"},"PeriodicalIF":2.7000,"publicationDate":"2023-09-20","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Geochronology","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.5194/gchron-5-361-2023","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"GEOCHEMISTRY & GEOPHYSICS","Score":null,"Total":0}

引用次数: 0

Abstract

Abstract. Extraction procedures for in situ cosmogenic 14C (in situ 14C) from quartz require quantitative isotopic yields while maintaining scrupulous isolation from atmospheric and organic 14C. These time- and labor-intensive procedures are ripe for automation; unfortunately, our original automated in situ 14C extraction and purification systems, reconfigured and retrofitted from our original systems at the University of Arizona, proved less reliable than hoped. We therefore installed a fully automated stainless-steel system (except for specific borosilicate glass or fused-silica components) incorporating more reliable valves and improved actuator designs, along with a more robust liquid nitrogen distribution system. As with earlier versions, the new system uses a degassed lithium metaborate (LiBO2) flux to dissolve the quartz sample in an ultra-high-purity oxygen atmosphere, after a lower-temperature combustion step to remove atmospheric and organic 14C. We compared single-use high-purity Al2O3 against reusable 90 %Pt / 10 %Rh (Pt/Rh) sample combustion boats. The Pt/Rh boats heat more evenly than the Al2O3, reducing procedural blank levels and variability for a given LiBO2 flux. This lower blank variability also allowed us to trace progressively increasing blanks to specific batches of fluxes from our original manufacturer. Switching to a new manufacturer returned our blanks to consistently low levels on the order of (3.4 ± 0.9) × 104 14C atoms. We also analyzed the CRONUS-A intercomparison material to investigate sensitivity of extracted 14C concentrations to the temperature and duration of the combustion and extraction steps. Results indicate that 1 h combustion steps at either 500 or 600 ∘C yield results consistent with the consensus value of Jull et al. (2015), while 2 h at 600 ∘C results in loss of ca. 9 % of the high-temperature 14C inventory. Results for 3 h extractions at temperatures ranging from 1050 to 1120 ∘C and 4.5 h at 1000 ∘C yielded similar results that agreed with the nominal value and published results from most laboratories. On the other hand, an extraction for 3 h at 1000 ∘C was judged to be incomplete due to a significantly lower measured concentration. Based on these results, our preferred technique is now combustion for 1 h at 500 ∘C followed by a 3 h extraction at 1050 ∘C. Initial analyses of the CoQtz-N intercomparison material at our lab yielded concentrations ca. 60 % lower than those of CRONUS-A, but more analyses of this material from this and other labs are clearly needed to establish a consensus value.

查看原文本刊更多论文

技术说明:研究偏酸锂的通量和提取方案，在PRIME实验室的一个新的全自动原位宇宙生成14C处理系统

摘要从石英中提取原位宇宙成因14C(原位14C)的过程需要定量的同位素产量，同时保持与大气和有机14C的严格隔离。这些耗时耗力的程序自动化的时机已经成熟;不幸的是，我们原来的自动化原位14C提取和净化系统，在亚利桑那大学的原始系统的基础上重新配置和改造，被证明不如预期的可靠。因此，我们安装了一个全自动不锈钢系统(除了特定的硼硅酸盐玻璃或熔融二氧化硅组件)，其中包括更可靠的阀门和改进的执行器设计，以及更坚固的液氮分配系统。与早期版本一样，新系统使用脱气偏酸锂(LiBO2)助熔剂将石英样品溶解在超高纯度的氧气气氛中，经过低温燃烧步骤去除大气和有机14C。我们比较了一次性高纯度Al2O3与可重复使用的90% Pt/ 10% Rh (Pt/Rh)样品燃烧船。Pt/Rh比Al2O3更均匀地加热，减少了给定LiBO2通量的程序空白水平和可变性。这种较低的毛坯可变性也使我们能够追踪逐渐增加的毛坯到原始制造商的特定批次的助焊剂。换了一家新的制造商后，我们的毛坯一直保持在(3.4±0.9)× 104个14C原子的低水平。我们还分析了CRONUS-A对比材料，以研究提取的14C浓度对燃烧和提取步骤的温度和持续时间的敏感性。结果表明，在500°C或600°C时，1小时的燃烧步骤产生的结果与Jull等人(2015)的共识值一致，而在600°C时，2小时的燃烧步骤导致约9%的高温14C库存损失。在1050到1120°C的温度下提取3小时，在1000°C的温度下提取4.5小时，得到的结果与大多数实验室公布的标称值和结果一致。另一方面，在1000°C下提取3小时被判定为不完全，因为测量到的浓度明显较低。根据这些结果，我们现在首选的方法是在500°C下燃烧1小时，然后在1050°C下提取3小时。我们实验室对CoQtz-N相互比较材料的初步分析得出的浓度比CRONUS-A低约60%，但显然需要从本实验室和其他实验室对该材料进行更多分析，以建立共识值。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊