Statistical analysis of hydrochemistry and isotopic characterization of groundwater from the Parecis Basin

Pub Date : 2021-01-01 DOI:10.1590/2318-0331.262120210087
M. R. Stradioto, E. H. Teramoto, H. K. Chang
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引用次数: 1

Abstract

ABSTRACT Knowledge of mechanism controlling the hydrochemistry of groundwater are crucial requirement to understand the hydrochemical evolution and evaluate the water quality of subsurficial water resources. Thus, to understand the process governing the hydrochemistry variability and flow dynamics of the Parecis and Ronuro Aquifers, the use of statistical analysis and isotopic characterization were combined. In the correlation matrix it was found that the highest correlation coefficient was observed for HCO3-, Ca2+, Mg2+, Sr2+, SO42-, and F-, which suggested that these parameters are derived from the same source, most likely from rock–water interactions. Additionally, we noticed moderate to high correlation among NO3-, Cl-, Na+, K+, and Ba2+, which collectively are indicative of domestic sewage contamination. Finally, a principal component analysis (PCA) identified that the most variance in hydrochemistry from the evaluated samples was controlled by HCO3-, Ca2+ and Mg2+, which is associated with rock–water interaction. Regarding the 18O and 2H isotope values, it could be observed that the aquifer recharges were of meteoric origin and that the Ronuro Aquifer samples were more enriched than the PAS samples. This work reinforces the capability of multivariate statistics to discern the main process that controls the variability of groundwater hydrochemistry.
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帕雷西斯盆地地下水水化学及同位素特征的统计分析
了解地下水水化学的控制机制是了解地下水水化学演化和评价地下水水质的重要条件。因此,为了了解控制parrecis和Ronuro含水层水化学变化和流动动力学的过程,将统计分析和同位素表征相结合。在相关矩阵中,发现HCO3-、Ca2+、Mg2+、Sr2+、SO42-和F-的相关系数最高,这表明这些参数来自同一来源,最有可能来自岩石-水相互作用。此外,我们注意到NO3-、Cl-、Na+、K+和Ba2+之间存在中高相关性,它们共同表明生活污水污染。最后,主成分分析(PCA)发现,评价样品的水化学变化主要受HCO3-、Ca2+和Mg2+控制,这与岩石-水相互作用有关。在18O和2H同位素值上,可以观察到含水层补给为大气来源,并且Ronuro含水层样品比PAS含水层样品更富集。这项工作加强了多元统计识别控制地下水水化学变化的主要过程的能力。
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