使用等离子发射探测器测量水中溶解的 Ne、Ar 和 N2 的新方法:地下水反硝化定量应用

IF 4.8 Q1 ENVIRONMENTAL SCIENCES ACS ES&T water Pub Date : 2024-08-22 DOI:10.1021/acsestwater.4c0017010.1021/acsestwater.4c00170
Matthew A. Coble, Karyne M. Rogers*, Jay Curtis, Rob van der Raaij, David J. Byrne, Axel Suckow and Uwe Morgenstern, 
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引用次数: 0

摘要

地下水脱硝研究需要仔细量化过量的 N2,以确定硝酸盐还原已经发生。对相应惰性气体 Ne 和 Ar 的测量可量化空气中过量的 N2 和原地脱气。我们首次比较了高精度四极杆质谱仪(QMS)与低成本 PlasmaDetek(等离子体发射探测器)气相色谱附加装置的测量结果,后者能够从单一样品中分析所有三种气体(N2、Ne、Ar),从而获得用于脱硝计算的可靠数据。这两种方法都可用于精确测量 N2、Ne 和 Ar 的浓度,其重复性和重叠性在 2σ 分析不确定性范围内。此外,我们还讨论了不同的地下水顶空气体采集方法,并表明吉根巴赫瓶虽然在长时间(数月或更长时间)储存样本时受到限制,但在较短储存时间(最多 2 或 3 周)内是可靠的,而冷压铜管采集方法则被认为在长时间(数年)内是稳定的。这种新型等离子检测器方法将使不具备先进惰性气体设施的实验室能够可靠地测量溶解的地下水气体(N2、Ne 和 Ar),用于地下水反硝化研究,了解地下自然硝酸盐衰减的影响,并改进集水区硝酸盐预算。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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New Method for Measuring Dissolved Ne, Ar, and N2 in Water Using a Plasma Emission Detector: Application for Quantifying Denitrification in Groundwater

Groundwater denitrification studies require the careful quantification of excess N2 to determine that nitrate reduction has taken place. The measurement of corresponding noble gases Ne and Ar quantifies excess air N2 and in situ degassing. We compare, for the first time, measurement results from a high-precision quadrupole mass spectrometer (QMS) with a low-cost PlasmaDetek (plasma emission detector) GC add-on capable of analyzing all three gases (N2, Ne, Ar) from a single sample to obtain reliable data for denitrification calculations. Both methods can be used to accurately measure N2, Ne, and Ar concentrations that are reproducible and overlap within 2σ analytical uncertainty. Moreover, we discuss different groundwater headspace gas collection methods and show that Giggenbach bottles, while limited when storing samples for long-time periods (months or more), are reliable over shorter storage periods (up to 2 or 3 weeks), compared to cold-pressed copper tube collection methods, which are deemed stable over long timeframes (years). This novel plasma detector method will enable laboratories that do not have state-of-the-art noble gas facilities to undertake reliable measurement of dissolved groundwater gases (N2, Ne, and Ar) for groundwater denitrification studies, understand the implications of natural subsurface nitrate attenuation, and improve catchment nitrate budgets.

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