Sources and fate of dissolved sulphate, carbonate, and nitrate in groundwater of the temperate climate zone: a high-resolution multi-isotope (H, C, O, S) study in north-eastern Germany*.

IF 1.1 4区环境科学与生态学 Q4 CHEMISTRY, INORGANIC & NUCLEAR

Isotopes in Environmental and Health Studies Pub Date : 2025-03-01 Epub Date: 2025-03-10 DOI:10.1080/10256016.2025.2461474

Anna-Kathrina Jenner, Christoph Malik, Gerd Böttcher, Patricia Roeser, Matthias Gehre, Iris Schmiedinger, Michael Ernst Böttcher

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引用次数: 0

Abstract

Different natural and anthropogenic drivers impact the groundwater in the catchment area of the southern Baltic Sea, north-eastern Germany. To understand the sources and fate of dissolved sulphate, carbonate, and nitrate on a regional scale, in the present study, the hydrogeochemical and multi-stable isotope (H, C, O, S) composition of groundwater samples from up to more than 300 sites (depths from near-surface down to 291 m) was studied. To investigate the element sources and the water-rock-microbe interaction processes that took place along the groundwater flow path, a mass balance approach is combined with physico-chemical modelling. Microbial oxidation of pyrite using nitrate as electron acceptor and a superimposition by dissimilatory sulphate reduction at depth is shown in a drilled vertical profile at one site. This trend frames the behaviour of sulphate at many investigated groundwater wells. Dissolved inorganic carbon (DIC) in the groundwater was found to be controlled by the uptake of biogenic carbon dioxide, the dissolution of carbonate minerals, the in situ oxidation of DOC and, at a few sites, the formation and/or oxidation of biogenic methane. Enhanced groundwater DIC loads may potentially increase future CO₂ degassing to the atmosphere upon release of groundwaters to the surface. These results form a comprehensive base for understanding the present situation and for future investigations.

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温带气候区地下水中溶解硫酸盐、碳酸盐和硝酸盐的来源和命运：德国东北部高分辨率多同位素（H， C， O， S）研究。

不同的自然和人为驱动因素影响了德国东北部波罗的海南部集水区的地下水。为了在区域尺度上了解溶解硫酸盐、碳酸盐和硝酸盐的来源和去向，本研究对300多个地点（近地表至291 m）地下水样品的水文地球化学和多稳定同位素（H， C， O， S）组成进行了研究。为了研究沿地下水流动路径发生的元素来源和水-岩石-微生物相互作用过程，将质量平衡方法与物理化学模型相结合。利用硝酸盐作为电子受体的黄铁矿的微生物氧化和在深度上由异化硫酸盐还原的叠加显示在一个地点的钻孔垂直剖面上。这一趋势描述了许多调查过的地下水井中硫酸盐的行为。研究发现，地下水中溶解无机碳（DIC）受生物成因二氧化碳的吸收、碳酸盐矿物的溶解、DOC的原位氧化以及少数地点生物成因甲烷的形成和/或氧化控制。地下水DIC负荷的增加可能会潜在地增加地下水释放到地表后向大气中脱气的二氧化碳。这些结果形成了一个全面的基础，了解现状和未来的调查。

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来源期刊

Isotopes in Environmental and Health Studies 环境科学-环境科学

CiteScore

2.80

自引率

7.70%

发文量

审稿时长

3.0 months

期刊介绍： Isotopes in Environmental and Health Studies provides a unique platform for stable isotope studies in geological and life sciences, with emphasis on ecology. The international journal publishes original research papers, review articles, short communications, and book reviews relating to the following topics: -variations in natural isotope abundance (isotope ecology, isotope biochemistry, isotope hydrology, isotope geology) -stable isotope tracer techniques to follow the fate of certain substances in soil, water, plants, animals and in the human body -isotope effects and tracer theory linked with mathematical modelling -isotope measurement methods and equipment with respect to environmental and health research -diagnostic stable isotope application in medicine and in health studies -environmental sources of ionizing radiation and its effects on all living matter