Mercury Content and Pools in Complex Polycyclic Soils From a Mountainous Area in Galicia (NW Iberian Peninsula)

IF 2 Q3 SOIL SCIENCE

Spanish Journal of Soil Science Pub Date : 2023-04-06 DOI:10.3389/sjss.2023.11192

A. Gómez-Armesto, M. Méndez-López, Andrea Parente-Sendín, Noemi Calvo-Portela, X. Pontevedra-Pombal, E. García-Rodeja, F. Alonso-Vega, J. Nóvoa-Muñoz

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Abstract

Atmospheric mercury (Hg) usually tends to accumulate in the upper horizons of soils. However, the physico-chemical characteristics of some soils, as well as pedogenetic processes, past climate changes, or soil degradation processes, can lead to a redistribution of mercury through the soil profile. In this work, the presence and accumulation of mercury was studied in three deep polycyclic soils from a mountainous area in NW Iberia Peninsula. The highest total Hg values (HgT) were found in the organic matter-rich O and A horizons of FL and MF profiles (169 and 139 μg kg−1, respectively) and in the illuvial horizon of RV (129.2 μg kg−1), with the latter two samples showing the maximum Hg reservoirs (29.3 and 29.0 mg m−2, respectively). Despite finding the highest Hg content in the surface horizons, considerable Hg reservoirs were also observed in depths higher than 40–50 cm, indicating the importance of taking into account these soil layers when Hg pools are evaluated at a global scale. Based on the mass transfer coefficients, we can rule out the contribution of parent material to the Hg accumulation in most of the horizons, thus indicating that pedogenetic processes are responsible for the Hg redistribution observed along the soil profiles. Finally, by means of principal component analysis (PCA) and stepwise linear regression we could assess the main soil components involved in the Hg accumulation in each soil horizon. Therefore, PC1 (organic matter and low stability Al-hummus complexes) showed a higher influence on the surface horizons, whereas PC2 (reactive Al-Fe complexes and medium-high Al-hummus complexes) and PC4 (crystalline Fe compounds and pHw) were more relevant in the Hg distribution observed in the deepest soil layers.

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加利西亚(伊比利亚半岛西北部)山区复杂多循环土壤的汞含量和汞池

大气中的汞通常会积聚在土壤的上层。然而，一些土壤的物理化学特征，以及土壤成因过程、过去的气候变化或土壤退化过程，都可能导致汞在土壤剖面中的重新分布。在这项工作中，研究了伊比利亚半岛西北部山区三种深层多环土壤中汞的存在和积累。总汞值（HgT）最高的是FL和MF剖面富含有机物的O和A层（分别为169和139μg kg−1）以及RV的冲积层（129.2μg kg–1），后两个样品显示出最大的汞储量（分别为29.3和29.0 mg m−2）。尽管在表层发现了最高的汞含量，但在40–50厘米以上的深度也观察到了相当多的汞库，这表明在全球范围内评估汞库时，考虑这些土层的重要性。根据传质系数，我们可以排除母体物质对大多数层位汞积累的贡献，从而表明土壤成因过程是沿土壤剖面观察到的汞再分配的原因。最后，通过主成分分析（PCA）和逐步线性回归，我们可以评估每个土壤层中参与汞积累的主要土壤成分。因此，PC1（有机物和低稳定性铝-鹰嘴豆泥复合物）对表层表现出更高的影响，而PC2（活性铝-铁复合物和中高铝-鹰嘴豆泥复合体）和PC4（结晶铁化合物和pHw）与在最深土层中观察到的汞分布更相关。

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

Spanish Journal of Soil Science SOIL SCIENCE-

CiteScore

2.20

自引率

0.00%

发文量

期刊介绍： The Spanish Journal of Soil Science (SJSS) is a peer-reviewed journal with open access for the publication of Soil Science research, which is published every four months. This publication welcomes works from all parts of the world and different geographic areas. It aims to publish original, innovative, and high-quality scientific papers related to field and laboratory research on all basic and applied aspects of Soil Science. The journal is also interested in interdisciplinary studies linked to soil research, short communications presenting new findings and applications, and invited state of art reviews. The journal focuses on all the different areas of Soil Science represented by the Spanish Society of Soil Science: soil genesis, morphology and micromorphology, physics, chemistry, biology, mineralogy, biochemistry and its functions, classification, survey, and soil information systems; soil fertility and plant nutrition, hydrology and geomorphology; soil evaluation and land use planning; soil protection and conservation; soil degradation and remediation; soil quality; soil-plant relationships; soils and land use change; sustainability of ecosystems; soils and environmental quality; methods of soil analysis; pedometrics; new techniques and soil education. Other fields with growing interest include: digital soil mapping, soil nanotechnology, the modelling of biological and biochemical processes, mechanisms and processes responsible for the mobilization and immobilization of nutrients, organic matter stabilization, biogeochemical nutrient cycles, the influence of climatic change on soil processes and soil-plant relationships, carbon sequestration, and the role of soils in climatic change and ecological and environmental processes.