Migration and transformation mechanisms of iron in clayey sediments during compaction: studies using simulation experiments

IF 2.4 3区 地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY
Rui Liu, Teng Ma, Xinyan Liu, Yantao Jian, Juan Chen
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Abstract

The behavior of iron (Fe) in clayey aquitards has a significant effect on the groundwater environment. However, the release processes and impact of Fe within clayey sediments during compaction remain unknown. Two groups of simulation experiments were carried out to demonstrate the migration and transformation mechanisms of Fe during clayey sediment compaction. Experiment A, which simulated a natural deposition condition, revealed that pressurization changed the reaction environment from oxidative to reductive by isolating oxygen. Oxidation of ferrous ions was followed by reduction dissolution of poorly crystalline Fe (III) and crystalline Fe (III) oxides. Under the microbial utilization of organic matter, the main transformation process of sediment Fe was the dissimilatory reduction of poorly crystalline Fe (III) oxides. The total Fe concentration in pore water was 0.09–11.61 mg/L, with ferrous ions predominating among the Fe species. The lower moisture content (\(\text{<}\)~36%) in the later stage of compaction inhibited the dissimilatory reduction of Fe (III), and the formation of Fe (II) minerals resulted in a decrease in Fe concentration. Experiment B, which simulated an artificial compaction state, revealed that the sediment Fe was primarily released by physical dissolution because of changes in pore structure and solubility. The concentration of total Fe in pore water was 0.02–1.96 mg/L, with a significant increase in response to a rapid increase in pressure. According to the estimates in the Chen Lake wetland (eastern China), the contribution of clay pore water release accounted for 19.9–31.9% of the average Fe concentration in groundwater during natural deposition.

压实过程中粘土沉积物中铁的迁移和转化机制:模拟实验研究
粘土含水层中铁(Fe)的行为对地下水环境有重大影响。然而,铁在粘土沉积物压实过程中的释放过程和影响仍然未知。为了证明粘土沉积物压实过程中铁的迁移和转化机制,我们进行了两组模拟实验。实验 A 模拟了自然沉积条件,发现加压通过隔绝氧气使反应环境从氧化型变为还原型。亚铁离子氧化后,结晶度较差的铁(III)和结晶的铁(III)氧化物被还原溶解。在微生物利用有机物的情况下,沉积物中铁的主要转化过程是差结晶铁(III)氧化物的异化作用还原过程。孔隙水中的总铁浓度为 0.09-11.61 mg/L,其中以亚铁离子为主。压实后期较低的含水量(36%)抑制了铁(III)的异纤还原,铁(II)矿物的形成导致铁的浓度下降。模拟人工压实状态的实验 B 表明,由于孔隙结构和溶解度的变化,沉积物中的铁主要是通过物理溶解释放出来的。孔隙水中总铁的浓度为 0.02-1.96 mg/L,在压力快速增加的情况下,总铁的浓度显著增加。根据陈湖湿地(中国东部)的估算,在自然沉积过程中,粘土孔隙水的释放量占地下水中铁平均浓度的 19.9-31.9%。
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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来源期刊
Hydrogeology Journal
Hydrogeology Journal 地学-地球科学综合
CiteScore
5.40
自引率
7.10%
发文量
128
审稿时长
6 months
期刊介绍: Hydrogeology Journal was founded in 1992 to foster understanding of hydrogeology; to describe worldwide progress in hydrogeology; and to provide an accessible forum for scientists, researchers, engineers, and practitioners in developing and industrialized countries. Since then, the journal has earned a large worldwide readership. Its peer-reviewed research articles integrate subsurface hydrology and geology with supporting disciplines: geochemistry, geophysics, geomorphology, geobiology, surface-water hydrology, tectonics, numerical modeling, economics, and sociology.
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