Journal
HYDROLOGICAL PROCESSES
Volume 35, Issue 3, Pages -Publisher
WILEY
DOI: 10.1002/hyp.14066
Keywords
buried‐ valley aquifer; groundwater; heterogeneity; hyporheic exchange; riparian; spectral analysis; surface water‐ groundwater interactions; water quality
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Funding
- National Science Foundation [EAR-PF 1855193]
- University of Cincinnati
- Duke Energy Foundation
- Miami Conservancy District on land by Great Parks of Hamilton County
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Groundwater, a primary source of drinking water globally, may face quality issues due to excess nutrients and emerging contaminants. Understanding the fate and transport of contaminants in groundwater systems is crucial for successful remediation strategies. High conductivity facies in groundwater systems play a key role in enhancing nutrient and contaminant delivery, particularly during storm events.
Groundwater is a primary source of drinking water worldwide, but excess nutrients and emerging contaminants could compromise groundwater quality and limit its usage as a drinking water source. As such contaminants become increasingly prevalent in the biosphere, a fundamental understanding of their fate and transport in groundwater systems is necessary to implement successful remediation strategies. The dynamics of surface water-groundwater (hyporheic) exchange within a glacial, buried-valley aquifer system are examined in the context of their implications for the transport of nutrients and contaminants in riparian sediments. High conductivity facies act as preferential flow pathways which enhance nutrient and contaminant delivery, especially during storm events, but transport throughout the aquifer also depends on subsurface sedimentary architecture (e.g. interbedded high and low conductivity facies). Temperature and specific conductance measurements indicate extensive hyporheic mixing close to the river channel, but surface water influence was also observed far from the stream-aquifer interface. Measurements of river stage and hydraulic head indicate that significant flows during storms (i.e., hot moments) alter groundwater flow patterns, even between consecutive storm events, as riverbed conductivity and, more importantly, the hydraulic connectivity between the river and aquifer change. Given the similar mass transport characteristics among buried-valley aquifers, these findings are likely representative of glacial aquifer systems worldwide. Our results suggest that water resources management decisions based on average (base) flow conditions may inaccurately represent the system being evaluated, and could reduce the effectiveness of remediation strategies for nutrients and emerging contaminants.
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