Contemporary and relic waters strongly decoupled in arid alpine environments

Brendan J. Moran, D. Boutt, L. A. Munk, Joshua D. Fisher
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Abstract

Deciphering the dominant controls on the connections between groundwater, surface water, and climate is critical to understanding water cycles in arid environments. Yet, persistent uncertainties in the fundamental hydrology of these systems remain. The growing demand for critical minerals such as lithium and associated water demands in the arid environments in which they often occur has amplified the urgency to address these uncertainties. We present an integrated hydrological analysis of the Dry Andes region utilizing a uniquely comprehensive set of tracer data (3H, 18O/2H) for these environments, paired directly with physical hydrological observations. We find two strongly decoupled hydrological systems that interact only under specific hydrogeological conditions where preferential conduits exist. The primary conditions creating these conduits are laterally extensive fine-grained evaporite and/or lacustrine units and perennial flowing streams connected with regional groundwater discharge sites. The efficient capture and transport of modern or “contemporary” water (weeks to years old) within these conduits is the primary control of the interplay between modern hydroclimate variations and groundwater aquifers in these environments. Modern waters account for a small portion of basin budgets but are critical to sustaining surface waters due to the existence of these conduits. As a result, surface waters near basin floors are disproportionally sensitive to short-term climate and anthropogenic perturbations. The framework we present describes a new understanding of the dominant controls on natural water cycles intrinsic to these arid high-elevation systems that will improve our ability to manage critical water resources.
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干旱高山环境中的当代水体与遗迹水体强烈脱钩
破解地下水、地表水和气候之间联系的主要控制因素对于了解干旱环境中的水循环至关重要。然而,这些系统的基本水文学仍然存在持续的不确定性。对锂等重要矿物日益增长的需求以及干旱环境中对水的需求,加剧了解决这些不确定性的紧迫性。我们利用针对这些环境的一套独特而全面的示踪剂数据(3H、18O/2H),直接与物理水文观测数据配对,对安第斯干地区进行了综合水文分析。我们发现了两个强烈分离的水文系统,它们只有在特定的水文地质条件下才能相互作用,在这些条件下存在优先导流通道。形成这些导流道的主要条件是横向分布的细粒蒸发岩和/或湖积岩单元,以及与区域地下水排放点相连的常年流淌的溪流。现代或 "当代 "水(数周至数年前)在这些导管中的有效捕获和输送是现代水文气候变迁与这些环境中地下水含水层之间相互作用的主要控制因素。现代水只占流域预算的一小部分,但由于这些导流道的存在,现代水对维持地表水至关重要。因此,盆地底部附近的地表水对短期气候和人为扰动异常敏感。我们提出的框架描述了对这些干旱高海拔系统固有的自然水循环主导控制的新理解,这将提高我们管理关键水资源的能力。
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