Hydrologic windows into the crystalline basement and their controls on groundwater flow patterns across the Paradox Basin, western USA

M. Person, J.C. McIntosh, J.-H. Kim, C. Noyes, L. Bailey, S. Lingrey, R. Krantz, D. Lucero, P. Reiners, G. Ferguson
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Abstract

Conceptual models of sedimentary basin groundwater flow systems typically assume that the crystalline basement acts as an impermeable boundary and can be neglected. In this study, we use hydrologic models constrained by isotopic and geochemical datasets to argue that the La Sal Mountains, Utah, USA, act as a hydrologic window into the Paradox Basin’s lower aquifer system and underlying crystalline basement. We conducted a sensitivity study in which we varied crystalline basement/laccolith permeability as well as fault zone connectivity along a cross-sectional transect from the La Sal Mountains to Lisbon Valley. When the crystalline basement/laccolith units are set at relatively permeable levels (10−14 m2), simulated tracers that include total dissolved solids, oxygen isotopic composition of pore fluids (δ18O), and groundwater residence times are in closest agreement with field measurements. Model results indicate that pore fluids in the basal aquifer system underlying the Paradox Formation confining unit are a mixture of relatively young meteoric fluids and older Paradox Formation brines. The presence of faults did not significantly modify fluid exchange between the upper and lower aquifer systems. This was due, in part, to underpressuring within the Paradox Formation. Our study concludes that the Paradox Basin represents a regional recharge area for the Colorado Plateau, with groundwater discharge occurring along the Colorado River within the Grand Canyon some 375 km away to the southwest. This is only possible with a permeable crystalline basement. Our findings help explain the genesis of Mississippi Valley-type ore deposits of the US Midcontinent, where the presence of a permeable basement may be useful in addressing issues related to solute mass and energy balance.
晶体基底的水文窗口及其对美国西部帕拉多克斯盆地地下水流模式的控制作用
沉积盆地地下水流系统的概念模型通常假定结晶基底是一个不可渗透的边界,可以忽略不计。在本研究中,我们利用同位素和地球化学数据集约束下的水文模型,论证了美国犹他州拉萨尔山脉是观察 Paradox 盆地下部含水层系统和底层结晶基底的水文窗口。我们进行了一项敏感性研究,在这项研究中,我们改变了结晶基底/岩溶渗透率,以及从拉萨尔山脉到里斯本谷的横断面断层带连通性。当结晶基底/岩溶单元的渗透率设定在相对较高的水平(10-14 平方米)时,模拟示踪剂(包括溶解固体总量、孔隙流体的氧同位素组成(δ18O)和地下水停留时间)与实地测量结果最为接近。模型结果表明,帕拉多克斯地层封闭单元下的基底含水层系统中的孔隙流体是相对年轻的流星流体和较老的帕拉多克斯地层卤水的混合物。断层的存在并没有明显改变上下含水层系统之间的流体交换。部分原因是帕拉多克斯地层内部压力不足。我们的研究得出结论,帕拉多克斯盆地是科罗拉多高原的区域补给区,地下水沿科罗拉多河排入西南约 375 千米外的大峡谷。这只有在具有渗透性的结晶基底上才有可能发生。我们的研究结果有助于解释美国中部大陆密西西比河谷型矿床的成因,在那里,可渗透基底的存在可能有助于解决与溶质质量和能量平衡有关的问题。
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