Temperature and radon-222 as tracer of groundwater flow: application to El Hamma geothermal aquifer system, southeastern Tunisia

Agoubi, Belgaçem; Souid, Faiza; Telahigue, Faten; Kharroubi, Adel

doi:10.1007/s12517-015-1998-x

Cited by 14 publications

(1 citation statement)

References 35 publications

(45 reference statements)

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“…This trend of hydraulic turnover time can also be confirmed by the results obtained for Group V (Table S24), where springs with longer hydraulic turnover time have low radon concentrations and vice versa. All these considerations are also confirmed by Choubey et al [31] and Belgacem et al [103] where they claim that radon levels in groundwater are highly variable following its genetic type and depth of groundwater circulation. It is also important to highlight that it is intended in the future to apply for this entire region an innovative model (LIFI-PATRAM) that integrated an AEM flow solution to simulate the flow and transport of radioactive contaminants [104].…”

Section: General Analysis Of Pls-pm Resultsmentioning

confidence: 61%

An Assessment of Groundwater Contamination Risk with Radon Based on Clustering and Structural Models

Martins

Pereira

Oliveira

et al. 2019

Water

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There is currently some controversy in the scientific community regarding the efficiency of the water–rock interaction process in the contamination of radon in groundwater. In this study, some difficulties were found in the sampling phase. Many of the water collection points are used for human consumption. As such, some municipalities did not want to collaborate. When this natural contaminant is undetectable to the human sense and may cause pulmonary neoplasms in the long term, it is difficult to obtain collaboration from the municipalities concerned. To overcome this controversy, it is important to understand that geogenic, climatic, hydrological, and topographic features may contribute to the effective transfer of radon from rocks to groundwater. In brief, this new approach combines the radon transfer from the geological substrate to the groundwater circulation through hierarchic agglomerative clustering (HAC) and partial least squares-path modeling (PLS-PM) methods. The results show that some lithologies with higher radon production may not always contribute to noticeable groundwater contamination. In this group, the high-fracturing density confirms the recharge efficiency, and the physical-chemical properties of the hydraulic environment (electric conductivity) plays the main role of radon unavailability in the water intended for human consumption. Besides, the hydraulic turnover time of the springs can be considered an excellent radiological indicator in groundwater. In the absence of an anomalous radioactive source near the surface, it means that the high-turnover time of the springs leads to a low-radon concentration in the water. Besides linking high-risk areas with a short period required to free local flow discharges, this study exposes the virtues of a new perspective of a groundwater contamination risk modeling.

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Section: General Analysis Of Pls-pm Resultsmentioning

confidence: 61%