GIS‐based prediction of stream chemistry using landscape composition, wet areas, and hydrological flow pathways

Tiwari, Tejshree; Lidman, Fredrik; Laudon, Hjalmar; Lidberg, William; Ågren, Anneli

doi:10.1002/2016jg003399

Cited by 21 publications

(22 citation statements)

References 68 publications

(107 reference statements)

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“…Furthermore, biogeochemical processes take place in the riparian and upslope compartments, which may lead to additional seasonal variability linked to mobilization and/or retention of C, N and P sources. Biogeochemical processes are temperature dependent, and they are also influenced by residence time (Hrachowitz et al, 2016) and by the presence/absence of reactants in biogeochemical hotspots such as the riparian zone (Pinay et al, 2015;Tiwari et al, 2017;Dick et al, 2015). In this respect, high temperature and low flow velocity during the summer season (leading to high residence time in the riparian zone) provide favorable conditions for riparian denitrification and DOC and SRP mobilization.…”

Section: Land-to-stream Transfermentioning

confidence: 99%

“…Seasonal concentration variability is traditionally explained by the varying contribution of several conceptual compartments (end-members) with distinct chemical signatures , the contribution of these compartments to stream discharge being controlled by changing hydroclimatic conditions on a seasonal basis. In addition, biogeochemical processes controlled by temperature and by the convergence of reactants in reactive hotspots such as the riparian zone (Pinay et al, 2015;Tiwari et al, 2017;Dick et al, 2015) could lead to temporal variability in the concentrations within different conceptual compartments. Thus the interplay of hydrological and biogeochemical processes controls stream NO − 3 , DOC and SRP concentrations (Thomas et al, 2016).…”

Section: Land-to-stream Transfermentioning

confidence: 99%

“…A comparison of export regimes in contrasting catchments representing different landscape types can be performed to investigate the effect of, for example, contrasting dominant land use, dominant flow paths or climate (Outram et al, 2014;Dupas et al, 2017;Minaudo et al, 2017), sometimes aided by the use of models (e.g., Dupas et al, 2016a;Hartmann et al, 2016). In headwater catchments, several studies have highlighted the important role of landscape heterogeneity within hillslopes (Herndon et al, 2015;Musolff et al, 2017), notably the crucial role of reactive zones such as riparian wetlands (Dick et al, 2015;Pinay et al, 2015;Tiwari et al, 2017) in controlling solute export regimes.…”

Section: Introductionmentioning

confidence: 99%

“…To upscale headwater signals to downstream reaches, previous landscape mixing models, i.e., "models mixing headwater signals in proportion to their patch coverage" (Tiwari et al, 2017), often lack consideration of temporal variability in headwater signals and explicit consideration of in-stream transformations (e.g., Laudon et al, 2011;Agren et al, 2014). Few opportunities exist to study the export regimes of several headwater catchments representing "archetypes" of the main landscape units in a larger catchment, for multiple solutes and on different time scales, and to compare headwater export regimes to the integral signal measured in downstream reaches.…”

Section: Introductionmentioning

confidence: 99%

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Carbon and nutrient export regimes from headwater catchments to downstream reaches

et al. 2017

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Abstract. Excessive amounts of nutrients and dissolved organic matter in freshwater bodies affect aquatic ecosystems. In this study, the spatial and temporal variability in nitrate (NO − 3 ), dissolved organic carbon (DOC) and soluble reactive phosphorus (SRP) was analyzed in the Selke (Germany) river continuum from three headwaters draining 1-3 km 2 catchments to two downstream reaches representing spatially integrated signals from 184-456 km 2 catchments. Three headwater catchments were selected as archetypes of the main landscape units (land use × lithology) present in the Selke catchment. Export regimes in headwater catchments were interpreted in terms of NO − 3 , DOC and SRP land-to-stream transfer processes. Headwater signals were subtracted from downstream signals, with the differences interpreted in terms of in-stream processes and contributions from point sources. The seasonal dynamics for NO − 3 were opposite those of DOC and SRP in all three headwater catchments, and spatial differences also showed NO − 3 contrasting with DOC and SRP. These dynamics were interpreted as the result of the interplay of hydrological and biogeochemical processes, for which riparian zones were hypothesized to play a determining role. In the two downstream reaches, NO − 3 was transported almost conservatively, whereas DOC was consumed and produced in the upper and lower river sections, respectively. The natural export regime of SRP in the three headwater catchments mimicked a point-source signal (high SRP during summer low flow), which may lead to overestimation of domestic contributions in the downstream reaches. Monitoring the river continuum from headwaters to downstream reaches proved effective to jointly investigate land-to-stream and instream transport, and transformation processes.

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Section: Land-to-stream Transfermentioning

confidence: 99%

Section: Land-to-stream Transfermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Carbon and nutrient export regimes from headwater catchments to downstream reaches

et al. 2017

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“…The chromophores of DOM are categorized into two overlapping groups that correspond to their excited state structure: (1) discreet chromophores which form singlet and triplet excited state species upon light absorption and (2) chargetransfer (CT) complexes which form between closely associated donor and acceptor groups. Discreet chromophores include olefins, carbonyls, and aromatic moieties (Kujawinski et al 2004;Gonsior et al 2009;Turro et al 2010). Singlet excited states of CDOM form when ground state electrons absorb light energy and are promoted to high-energy atomic orbitals, maintaining their original electronic spin state.…”

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confidence: 99%

Multiple linear regression models to predict the formation efficiency of triplet excited states of dissolved organic matter in temperate wetlands

McCabe

Arnold

2018

Limnology & Oceanography

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The source and composition of dissolved organic matter (DOM) dictates light absorption in surface waters. Sunlight absorption by chromophoric dissolved organic matter (CDOM) forms reactive intermediates and drives global organic carbon processing. Triplet excited states of CDOM ( 3 CDOM*) are primary reactive intermediates formed by sunlight absorption by CDOM.3 CDOM* also produce secondary reactive intermediates, including radicals and reactive oxygen species, which are active in biogeochemical pathways. The efficiency of 3 CDOM* formation (apparent quantum yield, AQY T ) depends on DOM composition, especially DOM molecular weight. This dependence may arise from the greater probability of forming intra-molecular chargetransfer (CT) complexes in high-molecular weight DOM that inhibit 3 CDOM* formation. There are few examples that demonstrate this in field samples. In this report, vegetation, general hydrology, and watershed characteristics for 39 temperate wetlands, which are critical sources of high-molecular weight DOM, from the United States were defined and related to DOM composition and AQY T . The DOM bulk composition was assessed using absorbance and fluorescence spectroscopies. AQY T was estimated under simulated sunlight using the probe 2,4,6-trimethylphenol. Relatively high AQY T values (7%) were observed in wetlands with long hydroperiods and > 50% cropland watershed land cover compared to wetlands with >50% forest watershed land cover (< 1-4%). Low molecular weight DOM (E2/E3 > 7 and SUVA 254 < 3 L mg-C 21 m 21) and autochthonous DOM (b/a > 0.7) had relatively high AQY T estimates ($ 10%), indicating that allocthonous, high-molecular weight compounds produce 3 CDOM* less efficiently than autochthonous DOM. The CT theory of DOM light absorption and internal light-screening offer mechanistic explanations for these trends.Naturally occurring dissolved organic matter (DOM) is a complex mixture of components including aromatics from terrestrial plants and biomacromolecules from primary and secondary aquatic producers (Wilson 1987;Stenson et al. 2003;Nebbioso and Piccolo 2013). Wetlands are integral sources of DOM to the hydrosphere and function as natural reactors in DOM transformation (Watanabe et al. 2012;Raymond and Spencer 2015). The relative inputs of terrestrial and aquatic DOM, and thus DOM composition, changes from headwaters and isolated wetlands (terrene wetlands) to wetlands associated with lake basins and rivers (lentic and lotic wetlands, respectively) (M€ unster and Chr ost 1990;Larson et al. 2014;Yu et al. 2015). In headwater systems with surrounding shrubs, trees, or emergent vegetation, inputs of DOM are dominated by terrestrial sources, such as plant matter and soil organic matter (allochthonous DOM). In contrast, the composition of DOM in systems with large open water regions and long water residence times is dominated by exo-metabolites from photoautotrophs and pelagic heterotrophs as well as products of photo-and microbialdegradation (autochthonous DOM) (M€ unster and Chr ost ...

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Inferring scale‐dependent processes influencing stream water biogeochemistry from headwater to sea

Tiwari

Buffam

Sponseller

et al. 2017

Limnology & Oceanography

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Understanding how scale‐dependent processes regulate patterns of water chemistry remains a challenge in aquatic biogeochemistry. This study evaluated how chemical properties of streams and rivers vary with drainage size and explored mechanisms that may underlie nonlinear changes with increasing scale. To do this, we contrasted concentrations of total organic carbon (TOC) with pH and cations (Ca and Mg) from 69 catchments in northern Sweden, spanning a size gradient from headwaters (< 0.01 km2) to major rivers and estuaries (> 100,000 km2). Across this gradient, we evaluated (1) changes in average concentrations and temporal variation, (2) scale breaks in catchment area‐concentration relationships, and (3) the potential importance of groundwater inputs and instream processes as drivers of change. Results indicated that spatial and temporal signals converge at ∼2–10 km2 as streams draining distinct headwater catchments coalesce and mix. Beyond 10 km2, streams tended to lose headwater signatures, reflecting a transition from shallow to deep groundwater influence. This was accompanied by a second break at ∼70–500 km2 corresponding to reduced spatial variability and a convergence of the response to snowmelt, as the dominance of deep groundwater influence increased with catchment scale. Larger catchments showed greater effect of instream processing on TOC, as concentrations predicted from the conservative mixing of upstream signals and dilution with deep groundwater were lower than measured. This study improves the understanding of scaling biogeochemical patterns and processes in stream networks, highlighting thresholds that imply shifts in the factors that shape variation in chemistry from headwaters to the sea.

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GIS‐based prediction of stream chemistry using landscape composition, wet areas, and hydrological flow pathways

Cited by 21 publications

References 68 publications

Carbon and nutrient export regimes from headwater catchments to downstream reaches

Carbon and nutrient export regimes from headwater catchments to downstream reaches

Multiple linear regression models to predict the formation efficiency of triplet excited states of dissolved organic matter in temperate wetlands

Inferring scale‐dependent processes influencing stream water biogeochemistry from headwater to sea

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