Abstract
Hydrologic exchange fluxes (HEFs) vary significantly along river corridors due to spatiotemporal changes in discharge and geomorphology. This variability results in the emergence of biogeochemical hot-spots and hot-moments that ultimately control solute and energy transport and ecosystem services from the local to the watershed scales. In this work, we use a reduced-order model to gain mechanistic understanding of river bank storage and sinuosity-driven hyporheic exchange induced by transient river discharge. This is the first time that a systematic analysis of both processes is presented and serves as an initial step to propose parsimonious, physics-based models for better predictions of water quality at the large watershed scale. The effects of channel sinuosity, alluvial valley slope, hydraulic conductivity, and river stage forcing intensity and duration are encapsulated in dimensionless variables that can be easily estimated or constrained. We find that the importance of perturbations in the hyporheic zone's flux, residence times, and geometry is mainly explained by two-dimensionless variables representing the ratio of the hydraulic time constant of the aquifer and the duration of the event (Γd) and the importance of the ambient groundwater flow (∆h*). Our model additionally shows that even systems with small sensitivity, resulting in small changes in the hyporheic zone extent, are characterized by highly variable exchange fluxes and residence times. These findings highlight the importance of including dynamic changes in hyporheic zones for typical HEF models such as the transient storage model.
Original language | English |
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Pages (from-to) | 8572-8595 |
Number of pages | 24 |
Journal | Water Resources Research |
Volume | 53 |
Issue number | 10 |
DOIs | |
State | Published - Oct 2017 |
Externally published | Yes |
Funding
This study was carried out thanks to Gomez-Velez’s startup funding from the Department of Earth & Environmental Science at New Mexico Tech. In addition, Gomez-Velez and Wilson are supported by the NSF (EAR- 1015100) and the New Mexico EPSCoR Track I (EAR-0814449) awarded to New Mexico Tech. Harvey is supported by USGS NAWQA and PES Programs. Cardenas is supported by NSF (EAR- 0955750, EAR-1343861, and EAR- 1344547). This work is also supported by the River Corridor Working Group of the USGS’s John Wesley Powell Center for Analysis and Synthesis. The authors thank William D. Stone, Mark Person, Fred M. Phillips, and Cliff Dahm for their valuable suggestions regarding this article. Finally, we thank the Associate Editor Olaf Cirpka, Daniel Cadol, and three anonymous reviewers for their insightful comments. Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government. The Supporting Information file contains all the output data used to generate the figures in the manuscript.
Funders | Funder number |
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Department of Earth & Environmental Science | |
River Corridor Working Group | |
USGS NAWQA | EAR- 0955750, EAR- 1344547, EAR-1343861 |
National Science Foundation | EAR-0814449, EAR- 1015100 |
U.S. Geological Survey |
Keywords
- dynamic flow
- hyporheic exchange
- meanders
- residence times
- river bank storage