Exploring landscape and geologic controls on spatial patterning of streambank groundwater discharge in a mixed land use watershed |
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| Authors: | Kevin E. Jackson Eric M. Moore Ashley M. Helton Adam B. Haynes Janet R. Barclay Martin A. Briggs |
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| Affiliation: | 1. Department of Natural Resources and the Environment, University of Connecticut, Storrs, Connecticut, USA;2. U.S. Geological Survey, New England Water Science Center, East Hartford, Connecticut, USA;3. U.S. Geological Survey, Observing Systems Division, Hydrologic Remote Sensing Branch, Storrs, Connecticut, USA |
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| Abstract: | Preferential groundwater discharge features along stream corridors are ecologically important at local and stream network scales, yet we lack quantification of the multiscale controls on the spatial patterning of groundwater discharge. Here we identify physical attributes that best explain variation in the presence and lateral extent of preferential groundwater discharges along two 5th order streams, the Housatonic and Farmington Rivers, and 32 1st to 4th order reaches across the Farmington River network. We mapped locations of preferential groundwater discharge exposed along streambanks using handheld thermal infrared cameras paired with high-resolution topographic and land use land cover datasets, surficial soil characteristic maps, and depth-to-bedrock geophysical measurements. The unconfined Housatonic River, MA, USA (12 km) had fewer discharge locations and less lateral extent (41 discharge locations with 38 m of active discharge/km of river) compared to the partially confined Farmington River, CT, USA (26 km; 169 discharge locations with 129 m of active discharge/km of river). Using a moving window analysis, we found along both rivers that discharge was more likely to occur where bank slopes were steeper, floodplain extent was narrower, and degree of confinement was higher. Along the Farmington River, groundwater discharge was more likely to occur where saturated hydraulic conductivity was higher and depth-to-bedrock was shallower. Among the 32 stream reaches surveyed (33.2 km of total stream length) within the Farmington River watershed, preferential discharge was observed in all but two stream reaches, varied from 0 to 25% of lateral extent along stream banks (mean = 6%), and was more likely to occur where stream reach slopes were steep, saturated hydraulic conductivity was high, and watershed urbanization was low. Our results show that, though both surface (e.g., topographic, land use land cover) and subsurface (e.g., soil characteristics, bedrock depth) factors control the prevalence of streambank preferential groundwater discharge, the dominant controls vary across valley settings and stream sizes. |
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| Keywords: | groundwater-surface water exchange remote sensing river morphology thermal infrared imagery water temperature |
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