Groundwater, Soil, and Vegetation Interactions at Discrete Riparian Inflow Points (DRIPs) and Implications for Boreal Streams

Groundwater, Soil, and Vegetation Interactions at Discrete Riparian Inflow Points (DRIPs) and Implications for Boreal Streams

Hydrological processes at hillslope and catchment scales explain a large part of stream chemistry dynamics through source-transport mechanisms from terrestrial to aquatic ecosystems. Riparian zones play a central role, as they exert a strong influence on the chemical signature of groundwater dischar...

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Main Authors: Stefan W. Ploum, Jason A. Leach, Hjalmar Laudon, Lenka Kuglerová
Format: Article
Language:English
Published: Frontiers Media S.A. 2021-07-01
Series:Frontiers in Water
Subjects:
riparian
stream
biogeochemistry
vegetation
drip
groundwater
Online Access:https://www.frontiersin.org/articles/10.3389/frwa.2021.669007/full
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spelling doaj-8522f7d2ca56407fbb6c161a5d2167c12021-07-30T05:49:30ZengFrontiers Media S.A.Frontiers in Water2624-93752021-07-01310.3389/frwa.2021.669007669007Groundwater, Soil, and Vegetation Interactions at Discrete Riparian Inflow Points (DRIPs) and Implications for Boreal StreamsStefan W. Ploum0Jason A. Leach1Jason A. Leach2Hjalmar Laudon3Lenka Kuglerová4Department of Forest Ecology and Management, Swedish University of Agricultural Sciences, Umeå, SwedenNatural Resources Canada, Canadian Forest Service, Sault Ste. Marie, ON, CanadaEnvironmental and Life Sciences Graduate Program, Trent University, Peterborough, ON, CanadaDepartment of Forest Ecology and Management, Swedish University of Agricultural Sciences, Umeå, SwedenDepartment of Forest Ecology and Management, Swedish University of Agricultural Sciences, Umeå, SwedenHydrological processes at hillslope and catchment scales explain a large part of stream chemistry dynamics through source-transport mechanisms from terrestrial to aquatic ecosystems. Riparian zones play a central role, as they exert a strong influence on the chemical signature of groundwater discharge to streams. Especially important are riparian areas where upslope subsurface flow paths converge, because they connect a large part of the catchment to a narrow section of the stream. Recent research shows that both in terrestrial and aquatic ecosystems, riparian convergence zones fulfill important biogeochemical functions that differ from surrounding riparian zones. Most catchment-scale conceptual frameworks focus on generalized hillslope-riparian-stream transects and do not explicitly consider riparian convergence zones. This study integrates collective work on hydrology, groundwater chemistry, vegetation and soils of discrete riparian inflow points (DRIPs) in a boreal landscape. We show that compared to adjacent riparian forests, DRIPs have groundwater levels that are consistently near the surface, and supply organic-rich water to streams. We suggest that interactions between hydrology, wetland vegetation, and peat soil development that occur in DRIPs leads to their unique groundwater chemistry and runoff dynamics. Stream-based studies show that across flow conditions, groundwater inputs from DRIPs to headwater reaches influence stream temperature, water chemistry and biology. As such, accounting for DRIPs can complement existing hillslope and stream observations, which would allow better representation of chemical and biological interactions associated with convergence of subsurface flow paths in riparian zones.https://www.frontiersin.org/articles/10.3389/frwa.2021.669007/fullriparianstreambiogeochemistryvegetationdripgroundwater
collection DOAJ
language English
format Article
sources DOAJ
author Stefan W. Ploum
Jason A. Leach
Jason A. Leach
Hjalmar Laudon
Lenka Kuglerová
spellingShingle Stefan W. Ploum
Jason A. Leach
Jason A. Leach
Hjalmar Laudon
Lenka Kuglerová
Groundwater, Soil, and Vegetation Interactions at Discrete Riparian Inflow Points (DRIPs) and Implications for Boreal Streams
Frontiers in Water
riparian
stream
biogeochemistry
vegetation
drip
groundwater
author_facet Stefan W. Ploum
Jason A. Leach
Jason A. Leach
Hjalmar Laudon
Lenka Kuglerová
author_sort Stefan W. Ploum
title Groundwater, Soil, and Vegetation Interactions at Discrete Riparian Inflow Points (DRIPs) and Implications for Boreal Streams
title_short Groundwater, Soil, and Vegetation Interactions at Discrete Riparian Inflow Points (DRIPs) and Implications for Boreal Streams
title_full Groundwater, Soil, and Vegetation Interactions at Discrete Riparian Inflow Points (DRIPs) and Implications for Boreal Streams
title_fullStr Groundwater, Soil, and Vegetation Interactions at Discrete Riparian Inflow Points (DRIPs) and Implications for Boreal Streams
title_full_unstemmed Groundwater, Soil, and Vegetation Interactions at Discrete Riparian Inflow Points (DRIPs) and Implications for Boreal Streams
title_sort groundwater, soil, and vegetation interactions at discrete riparian inflow points (drips) and implications for boreal streams
publisher Frontiers Media S.A.
series Frontiers in Water
issn 2624-9375
publishDate 2021-07-01
description Hydrological processes at hillslope and catchment scales explain a large part of stream chemistry dynamics through source-transport mechanisms from terrestrial to aquatic ecosystems. Riparian zones play a central role, as they exert a strong influence on the chemical signature of groundwater discharge to streams. Especially important are riparian areas where upslope subsurface flow paths converge, because they connect a large part of the catchment to a narrow section of the stream. Recent research shows that both in terrestrial and aquatic ecosystems, riparian convergence zones fulfill important biogeochemical functions that differ from surrounding riparian zones. Most catchment-scale conceptual frameworks focus on generalized hillslope-riparian-stream transects and do not explicitly consider riparian convergence zones. This study integrates collective work on hydrology, groundwater chemistry, vegetation and soils of discrete riparian inflow points (DRIPs) in a boreal landscape. We show that compared to adjacent riparian forests, DRIPs have groundwater levels that are consistently near the surface, and supply organic-rich water to streams. We suggest that interactions between hydrology, wetland vegetation, and peat soil development that occur in DRIPs leads to their unique groundwater chemistry and runoff dynamics. Stream-based studies show that across flow conditions, groundwater inputs from DRIPs to headwater reaches influence stream temperature, water chemistry and biology. As such, accounting for DRIPs can complement existing hillslope and stream observations, which would allow better representation of chemical and biological interactions associated with convergence of subsurface flow paths in riparian zones.
topic riparian
stream
biogeochemistry
vegetation
drip
groundwater
url https://www.frontiersin.org/articles/10.3389/frwa.2021.669007/full
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