High-throughput isotope analysis of sub-nanogram sized lead using MC-ICP-MS with on-line thallium doping technique and desolvating nebulizer system
K. Nagaishi, R. Nakada, T. Ishikawa
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Abstract
Copyright © 2021 by The Geochemical Society of Japan. Hattori et al., 2017). However, both the ion detection yield and gain of the MIC detector can change through the long term continuous detection of analytes, and thus, careful monitoring and calibration of gain are necessary to achieve accurate analyses (Paul et al., 2005; Kent, 2008). The development of more convenient, precise isotope analysis of small-sized Pb samples still has great significance in terms of analyses of a large number of samples in geological, geochemical, and environmental studies. The MC-ICP-MS method with thallium (Tl) doping technique (e.g., Hirata, 1996; Collerson et al., 2002; Kamenov et al., 2004; Tanimizu and Ishikawa, 2006) has excellent potential to be used for this purpose. In this method, Pb sample solution doped with a standard Tl is used, and the measured 205Tl/203Tl ratios are utilized for the correction of mass discrimination effects for Pb isotopes during MC-ICP-MS analyses. Precise isotope analysis of sub-nanogram sized Pb sample is potentially achievable by the use of amplifiers with higher resistor and desolvating nebulizer system, which increases electrical signal/noise ratios and sample introduction efficiency, respectively. However, combined use of Tl doping technique and desolvating nebulizer system is not well established. This is because gradual oxidation of Tl+ to Tl3+ occurs under the presence of Pb2+, which causes a change of mass bias factor for Tl isotopes mainly due to preferential transmission of Tl isotopes through the desolvating process (Kamenov et al., 2004). To prevent this effect, Pb isotope measurement must be carried out within an hour after the Tl doping (Kamenov et al., 2004). OtherHigh-throughput isotope analysis of sub-nanogram sized lead using MC-ICP-MS with on-line thallium doping technique and desolvating nebulizer system
利用MC-ICP-MS在线铊掺杂技术和脱溶雾化系统对亚纳克级铅进行高通量同位素分析
日本地球化学学会版权所有©2021。Hattori等人,2017)。然而,通过对分析物的长期连续检测,MIC检测器的离子检测产率和增益都可能发生变化,因此,为了实现准确的分析,需要仔细监测和校准增益(Paul et al., 2005;肯特,2008)。开发更方便、更精确的小尺寸Pb样品同位素分析方法,对于地质、地球化学和环境研究中大量样品的分析仍具有重要意义。采用铊掺杂技术的MC-ICP-MS方法(例如,Hirata, 1996;Collerson et al., 2002;Kamenov et al., 2004;Tanimizu and Ishikawa, 2006)具有用于此目的的极好潜力。在该方法中,使用掺杂标准Tl的Pb样品溶液,并利用测量的205Tl/203Tl比例来校正MC-ICP-MS分析中Pb同位素的质量分辨效应。通过使用具有更高电阻的放大器和脱溶雾化器系统,可以实现亚纳克大小的Pb样品的精确同位素分析,从而分别提高电信号/噪声比和样品引入效率。然而,Tl掺杂技术与脱溶雾化器系统的结合使用还没有很好的建立起来。这是因为在Pb2+的存在下,Tl+逐渐氧化为Tl3+,这导致Tl同位素的质量偏差因子发生变化,这主要是由于Tl同位素在脱盐过程中优先传输(Kamenov et al., 2004)。为了防止这种影响,必须在Tl掺杂后一小时内进行铅同位素测量(Kamenov et al., 2004)。利用MC-ICP-MS在线铊掺杂技术和脱溶雾化系统对亚纳克级铅进行高通量同位素分析
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