Chemostatic concentration–discharge behaviour observed in a headwater catchment underlain with discontinuous permafrost

Conroy, Nathan; Dann, J.; Newman, Brent D.; Heikoop, Jeffrey M.; Arendt, Carli A.; Busey, Bob; Wilson, Cathy J.; Wullschleger, Stan D.

doi:10.1002/hyp.14591

Cited by 5 publications

(6 citation statements)

References 33 publications

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“…The relatively fast cation-exchange reactions, compared to timescales for clay precipitation, make Ca 2+ more susceptible to changes associated with discharge, which we propose as the cause of slightly lower, but still chemostatic, C-Q slopes of these divalent cations compared to Al 3+ and SiO 2(aq) . This weak chemostasis for divalent cations, relative to Al 3+ and SiO 2(aq) , has been observed in other catchments (Conroy et al, 2022;Godsey et al, 2009Godsey et al, , 2019Herndon et al, 2015;Kim et al, 2017) but is rarely attributed to cation exchange.…”

Section: Chemostasis Primarily Driven By Silicate Mineral Dissolution...mentioning

confidence: 67%

“…However, despite the large number of C-Q studies, few investigate how the geochemical processes that shape groundwater chemistry evolve along flowpaths before contributing to streamflow. For example, many C-Q studies have report chemostasis for both SiO 2(aq) and/or Al 3+ as well as still chemostatic but slightly more negative C-Q slopes for Ca 2+ and/or Mg 2+ for a variety of catchments (Conroy et al, 2022;Godsey et al, 2009Godsey et al, , 2019Herndon et al, 2015;Kim et al, 2017), highlighting the potential for geochemical reactions to impact individual solutes differently. Here, we investigate the coupled geochemical reactions that happen along groundwater flowpaths, including (1) primary mineral dissolution leading to (2) clay precipitation and (3) subsequent cation-exchange reactions.…”

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confidence: 99%

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Water‐rock interactions drive chemostasis

Warix,

Navarre‐Sitchler,

Singha

2024

Hydrological Processes

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The western U.S. is experiencing shifts in recharge due to climate change, and it is currently unclear how hydrologic shifts will impact geochemical weathering and stream concentration–discharge (C–Q) patterns. Hydrologists often use C–Q analyses to assess feedbacks between stream discharge and geochemistry, given abundant stream discharge and chemistry data. Chemostasis is commonly observed, indicating that geochemical controls, rather than changes in discharge, are shaping stream C–Q patterns. However, few C–Q studies investigate how geochemical reactions evolve along groundwater flowpaths before groundwater contributes to streamflow, resulting in potential omission of important C–Q controls such as coupled mineral dissolution and clay precipitation and subsequent cation exchange. Here, we use field observations—including groundwater age, stream discharge, and stream and groundwater chemistry—to analyse C–Q relations in the Manitou Experimental Forest in the Colorado Front Range, USA, a site where chemostasis is observed. We combine field data with laboratory analyses of whole rock and clay x‐ray diffraction and soil cation‐extraction experiments to investigate the role that clays play in influencing stream chemistry. We use Geochemist's Workbench to identify geochemical reactions driving stream chemistry and subsequently suggest how climate change will impact stream C–Q trends. We show that as groundwater age increases, C–Q slope and stream solute response are not impacted. Instead, primary mineral dissolution and subsequent clay precipitation drive strong chemostasis for silica and aluminium and enable cation exchange that buffers calcium and magnesium concentrations, leading to weak chemostatic behaviour for divalent cations. The influence of clays on stream C–Q highlights the importance of delineating geochemical controls along flowpaths, as upgradient mineral dissolution and clay precipitation enable downgradient cation exchange. Our results suggest that geochemical reactions will not be impacted by future decreasing flows, and thus where chemostasis currently exists, it will continue to persist despite changes in recharge.

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Section: Chemostasis Primarily Driven By Silicate Mineral Dissolution...mentioning

confidence: 67%

mentioning

confidence: 99%

Water‐rock interactions drive chemostasis

Warix,

Navarre‐Sitchler,

Singha

2024

Hydrological Processes

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“…While the above conceptual model was developed and refined over several decades, there remains limited longer‐term multi‐year data sets that combine flows with water quality and DOC, particularly in permafrost‐underlain watersheds (Conroy et al, 2022; Gandois et al, 2021; Koch et al, 2021; Shogren et al, 2019). In addition, how catchment spatial structure influences these flow‐chemistry patterns is less clear, as riparian and hillslope contributions in cold environments have not been clearly defined.…”

Section: Discussionmentioning

confidence: 99%

“…This high dispersion can be introduced by multiple factors including: (1) source and transport limitations (Benettin et al, 2017); (2) in‐stream biogeochemical transformations disconnected from hydrological changes (Bieroza & Heathwaite, 2015; Moatar et al, 2017); and (3) long‐term and seasonal variations (Hirsch, 2014; Zhang et al, 2016). Monitoring of C–Q patterns over seasons and a range of flow conditions have been explored using high‐frequency methods across temperate to snow‐dominated catchments (Andrea et al, 2006; Bende‐Mischl, Verburg and Cresswell, 2013; Vaughan et al, 2017; Burns et al, 2019; Knapp et al, 2020), although implementation in northern environments is less common (Conroy et al, 2022; Gandois et al, 2021; Koch et al, 2021; Shogren et al, 2021). Increased resolution monitoring is particularly important in high latitude environments where seasonality combined with a heterogeneous soil profile exerts considerable control over stream solutes and flow volume.…”

Section: Introductionmentioning

confidence: 99%

Multi‐year high‐frequency sampling provides new runoff and biogeochemical insights in a discontinuous permafrost watershed

Shatilla

Tang

Carey

2023

Hydrological Processes

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Permafrost‐underlain watersheds in the subarctic are sensitive to warming as small changes in ground thermal status will alter all components of the hydrological cycle. Globally, observed increases in winter flows and shifting water chemistry have most often been ascribed to permafrost thaw and deepening runoff pathways. However, there remain few studies in headwater catchments that examine coupled flow‐chemistry relations at high frequency over multiple years and seasons to evaluate the implications of environmental change. In this study, we use multi‐year high‐frequency measurement of discharge, specific conductance (SpC) and chromophoric dissolved organic matter (CDOM) along with traditional grab sampling of major ions to understand the sources and pathways of water and evaluate how distinct solutes are mobilized in a well‐studied subarctic basin in Yukon, Canada. Seasonally, the catchment exhibited considerable hysteresis in flow‐solute relations and had both chemostatic and dilution SpC–Q patterns with respect to major ions depending upon season and mobilization CDOM–Q signals. Storm events were extracted from high‐frequency data and normalized C–Q indices were determined and related to flow, catchment and meteorological variables. CDOM–Q events predominantly had an anti‐clockwise hysteresis and increases in DOC concentrations during storms, with some exception in the spring and fall. Conversely, SpC–Q events exhibited clockwise hysteresis and a dilution behaviour during events with less seasonal or inter‐annual variability. Information from this study supports previous conceptual models of thermally regulated runoff generation in a layered soil profile, yet also points to the importance of lateral connectivity and distal sources of solutes.

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“…A. Rose et al, 2018;Thompson et al, 2011) Pairing δD and δ 18 O with C-Q 1 2 years of 30-min continuous data from automated field laboratory (Knapp et al, 2020) Discrete 2 2 years of sub-weekly frequency automated grab samples (Conroy et al, 2022) 3 3 years of sub-monthly frequency grab samples (F. Liu et al, 2017) Spectral analysis 1 >20 years of daily data (Cheng et al, 2021) Cross-scale 2 5 years of hourly data (Heathwaite & Bieroza, 2021) 3 ≥2 years of 15-min data (Jiang et al, 2020;Wenng et al, 2021) Fractal scaling 1 2 years of 7-h data and long-term weekly data (Kirchner & Neal, 2013) Cross-scale 2 ≥2 years of 15-min data (Hansen & Singh, 2018;Jiang et al, 2020) 3 >3 years of daily grab sample data (Aubert et al, 2014) C-Q moving window 1 >5 years of daily data (Fazekas et al, 2021;Zimmer et al, 2019) Cross-scale 2 ≥2 years of 15-min data (Fazekas et al, 2020;Wymore et al, 2021) Dynamic time warping & clustering methods 1 1 year of daily concentrations averaged across ≥1 year(s) of data (Bolotin et al, 2023) Cross-scale 2 >3 years of subhourly sensor data (Javed et al, 2021) Note: "Discrete" refers to approaches focused on single time scales; we note that this does not mean these analyses cannot be done at multiple time scales and compared. Thus, comparisons across time scales using discrete methods are indirect.…”

Section: Discrete Versus Cross-scalementioning

confidence: 99%

Catchment concentration–discharge relationships across temporal scales: A review

Speir,

Rose,

Blaszczak

et al. 2023

WIREs Water

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Processes that drive variability in catchment solute sourcing, transformation, and transport can be investigated using concentration–discharge (C–Q) relationships. These relationships reflect catchment and in‐stream processes operating across nested temporal scales, incorporating both short and long‐term patterns. Scientists can therefore leverage catchment‐scale C–Q datasets to identify and distinguish among the underlying meteorological, biological, and geological processes that drive solute export patterns from catchments and influence the shape of their respective C–Q relationships. We have synthesized current knowledge regarding the influence of biological, geological, and meteorological processes on C–Q patterns for various solute types across diel to decadal time scales. We identify cross‐scale linkages and tools researchers can use to explore these interactions across time scales. Finally, we identify knowledge gaps in our understanding of C–Q temporal dynamics as reflections of catchment and in‐stream processes. We also lay the foundation for developing an integrated approach to investigate cross‐scale linkages in the temporal dynamics of C–Q relationships, reflecting catchment biogeochemical processes and the effects of environmental change on water quality.This article is categorized under: Science of Water > Hydrological Processes Science of Water > Water Quality Science of Water > Water and Environmental Change

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Chemostatic concentration–discharge behaviour observed in a headwater catchment underlain with discontinuous permafrost

Cited by 5 publications

References 33 publications

Water‐rock interactions drive chemostasis

Water‐rock interactions drive chemostasis

Multi‐year high‐frequency sampling provides new runoff and biogeochemical insights in a discontinuous permafrost watershed

Catchment concentration–discharge relationships across temporal scales: A review

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