Journal
HYDROLOGICAL PROCESSES
Volume 36, Issue 3, Pages -Publisher
WILEY
DOI: 10.1002/hyp.14559
Keywords
concentration-discharge relationships; end-member mixing analysis; near-surface runoff; sleepers river; snowmelt; solute transport
Categories
Funding
- Ecosystem Science Center, Michigan Technological University
- USDA Forest Service Northern Research Station
- USDA-McIntire Stennis Fund [1024731]
- USGS Land Change Science program
- USGS Water Energy and Biogeochemical Budgets (WEBB)
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Previous studies on concentration-discharge (C-Q) relationships have focused on short-term or low-temporal resolution data, providing limited insight on catchment response over time or to climate change. In this study, using 15 solutes data from 1992 to 2015 at Sleepers River Research Watershed, the researchers compared C-Q relationships over decades, years, and seasons. They applied end-member mixing analysis (EMMA) to identify solute sources and flow path routing. The results showed that shifting mixing proportions of near-surface runoff (NSR), riparian groundwater, and hillslope hollow groundwater accounted for the temporal variability of conservative solutes in streamflow. The researchers also found that the b-coefficient of the C-Q relation decreased significantly with an increase in the groundwater to NSR concentration ratio for conservative solutes. Additionally, the strength of dilution or flushing was stronger during the snowmelt period compared to other seasons. These findings provide more tools for the interpretation of catchment processes and responses to climate change.
Past studies on concentration-discharge (C-Q) relationships have focused on short-term or low-temporal resolution data. While advancing understanding of catchment processes, these studies provided limited insight on catchment response over time or to climate change. Using 15 solutes from 1992 to 2015 at Sleepers River Research Watershed, Vermont, we compared C-Q relationships over decades, years, and seasons to elucidate controls on stream chemical variation. We applied end-member mixing analysis (EMMA) to identify solute sources and flow path routing. EMMA identified three end-members: near-surface runoff (NSR), riparian groundwater, and hillslope hollow groundwater. Shifting mixing proportions of these end-members accounted for the temporal variability of conservative (no chemical reaction en route from source to stream) solutes in streamflow. For example, an increase in NSR fraction, typical of high flow, caused flushing (increased concentrations) of NO3-, DOC, Al, and Fe, which were greatest in NSR, dilution of specific conductance and base cation, SO42-, Si, Sr, Ba, and Mn concentrations, which were greatest in the two groundwater end-members. This behaviour is reflected in the b-coefficient of the C-Q relation (C = aQ(b)), which indicates the strength of dilution (b < -0.1) and flushing (b > 0.1) effects. For conservative solutes, the b-coefficient decreased significantly (p < 0.01) with an increase in the groundwater to NSR concentration ratio. Solutes that are conservative and have relatively constant concentrations in end-members over time showed consistent annual C-Q patterns over years and decades. Furthermore, the strength of dilution or flushing was stronger during the snowmelt period, when the NSR fraction peaked, than during the dormant and growing seasons. With shorter snowmelt periods and snow to rain shifts, the flushing or dilution power of snowmelt runoff will weaken and alter catchment response to climate change. These insights provide more tools for the interpretation of catchment processes and responses to climate change.
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