Headwater lakes and their influence on downstream discharge

Leach, Jason A.; Laudon, Hjalmar

doi:10.1002/lol2.10110

Cited by 29 publications

(43 citation statements)

References 36 publications

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“…Our assumption is further based on modelling studies of weathering rates in a soil transect in the Krycklan catchment, which indicates that there is a kinetic control of the release of BCs in the soils (Erlandsson et al, 2016). Since all BCs behave relatively conservatively in these environments (Ledesma et al, 2013;Lidman et al, 2014), we used their combined concentration as a proxy for soil contact time. However, the assumption is only valid when the water is in contact with mineral soils, not with peat in mires, which are abundant in some of the investigated sub-catchments.…”

Section: Linking Seasonal Base Cation Concentration and Isotopic Signature To Travel Times To Stream Watermentioning

confidence: 99%

How catchment characteristics influence hydrological pathways and travel times in a boreal landscape

Sterte

Lidman

Lindborg³

et al. 2021

Hydrol. Earth Syst. Sci.

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Abstract. Understanding travel times and hydrological pathways of rain and snowmelt water transported through the landscape to recipient surface waters is critical in many hydrological and biogeochemical investigations. In this study, a particle-tracking model approach in Mike SHE was used to investigate the pathway and its associated travel time of water in 14 partly nested, long-term monitored boreal sub-catchments of the Krycklan catchment (0.12–68 km2). This region is characterized by long and snow-rich winters with little groundwater recharge and highly dynamic runoff during spring snowmelt. The geometric mean of the annual travel time distribution (MTTgeo) for the studied sub-catchments varied from 0.8 to 2.7 years. The variations were related to the different landscape types and their varying hydrological responses during different seasons. Winter MTTgeo ranged from 1.2 to 7.7 years, while spring MTTgeo varied from 0.5 to 1.9 years. The modelled variation in annual and seasonal MTTgeo and the fraction of young water (<3 months) was supported by extensive observations of both δ18O and base cation concentrations in the different streams. The travel time of water to streams was positively correlated with the area coverage of low-conductive silty sediments (r=0.90, P<0.0001). Catchments with mixed soil–landscape settings typically displayed larger variability in seasonal MTTgeo, as contrasting hydrological responses between different soil types (e.g. peat in mires, till and silty sediments) are integrated. The areal coverage of mires was especially important for the young water contribution in spring (r=0.96, P<0.0001). The main factor for this was attributed to extensive soil frost in mires, causing considerable overland flow during the snowmelt period. However, this lower groundwater recharge during snowmelt caused mire-dominated catchments to have longer stream runoff MTTgeo than comparable forest catchments in winter. Boreal landscapes are sensitive to climate change, and our results suggest that changes in seasonality are likely to cause contrasting responses in different catchments depending on the dominating landscape type.

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Section: Linking Seasonal Base Cation Concentration and Isotopic Signature To Travel Times To Stream Watermentioning

confidence: 99%

How catchment characteristics influence hydrological pathways and travel times in a boreal landscape

Sterte

Lidman

Lindborg³

et al. 2021

Hydrol. Earth Syst. Sci.

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“…Previous studies have the examined the spatial extent of lake influence on stream water characteristics. One such study used measurements of streamflow and water isotopes to examine the direct contributions of lake water to streams, and found that these contributions constitute a declining fraction of stream water across a distance from 1.4 to 4.2 km downstream of a lake (Leach & Laudon, 2019). An additional study examining sediment dynamics in a montaine stream‐lake network suggested that lakes act as sediment sinks, and thereby deplete the sediment content of lake outlet streams (Arp et al, 2007).…”

Section: Discussionmentioning

confidence: 99%

“…Previous studies have also examined temporal variations in the contributions of upstream lakes to stream water. Measurements of streamflow and water isotopes performed by Leach and Laudon (2019) estimated that these direct contributions of lake water to streams are greatest during periods of moderate to high discharge. This may seem contrary to our findings of higher stream temperature response to lakes are at low discharge.…”

Section: Discussionmentioning

confidence: 99%

“…Lake influence on stream temperature may be substantial where a large portion of stream water has originated from an upstream lake, but will be absent where no upstream lakes are present. This fundamental hydrologic partitioning may influence many stream characteristics, and has been reflected in observed patterns of stream sediment load (Arp et al, 2007) and the composition of water isotopes (Leach & Laudon, 2019) along streams draining lakes. Lake‐sourced contributions to streamflow at any single point may also vary over time due to changing amounts of runoff from above‐lake and below‐lake contributing areas (Leach et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

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Describing alpine lake influence on stream network temperatures: A statistical modelling approach

Carlson

Poole

2021

Hydrological Processes

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“…There should, therefore, be a significant relationship between the simulated travel times a nd the observed winter isotopic stream signature provided that the model performs well. Some of the sub-catchments are, however, affected by evaporation from lake surfaces that result in isotopic fractionation (Leach and Laudon, 2019). Th is fractionation must be accounted for in order to use the signature as a representation of the groundwater.…”

Section: Observations Of Stable Isotopesmentioning

confidence: 99%

Linking groundwater travel times to stream chemistry, isotopic composition and catchment characteristics

Sterte

Lidman

Lindborg³

et al. 2020

Preprint

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Abstract. Understanding travel times of rain and snowmelt inputs transported through the subsurface environment to recipient surface waters is critical in many hydrological and biogeochemical investigations. In this study, a particle tracking model approach in Mike SHE was used to investigating the travel time of stream groundwater input to 14 partly nested, long-term monitored boreal sub-catchments. Based on previous studies in the area, we hypothesized that the main factor controlling groundwater travel times was catchment size. The modeled mean travel time (MTT) in the different sub-catchments ranged between 0.5 years and 3.6 years. Estimated MTTs were tested against the observed long-term winter isotopic signature (δ2H, δ18O) and chemistry (base cation concentration and pH) of the stream water. The underlying assumption was that older water would have an isotopic signature that resembles the long-term average precipitation input, while seasonal variations would be more apparent in catchments with younger water. Similarly, it was assumed that older water would be more affected by weathering, resulting in higher concentrations of base cations and higher pH. 10-year average winter values for stream chemistry were used for each sub-catchment. We found significant correlations between the estimated travel times and average water isotope signature (r = 0.80, p

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Headwater lakes and their influence on downstream discharge

Cited by 29 publications

References 36 publications

How catchment characteristics influence hydrological pathways and travel times in a boreal landscape

How catchment characteristics influence hydrological pathways and travel times in a boreal landscape

Describing alpine lake influence on stream network temperatures: A statistical modelling approach

Linking groundwater travel times to stream chemistry, isotopic composition and catchment characteristics

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