Upscaling Nitrogen Removal Capacity from Local Hotspots to Low Stream Orders’ Drainage Basins

Pinay, Gilles; Peiffer, Stefan; Dreuzy, Jean‐Raynald de; Krause, Stefan; Hannah, David M.; Fleckenstein, Jan H.; Sébilo, Mathieu; Bishop, Kevin; Hubert‐Moy, Laurence

doi:10.1007/s10021-015-9878-5

Cited by 122 publications

(165 citation statements)

References 147 publications

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“…Low-order (headwater) streams are important in the downstream transport of diffuse nitrate (Alexander et al 2007). However, rivers are not inert pipelines, on the contrary, they are actually biogeochemical hot spots (Benstead and Leigh 2012;McClain et al 2003;Pinay et al 2015), which also play a major role in the transformation of reactive nitrogen to less ecologically active forms (Bernhardt et al 2005;Bernot and Dodds 2005). Across large catchments, nitrate attenuation is inversely correlated with stream-order, due to the relatively large surface area to volume ratios in smaller streams which aids surface water contact with the hypoxic bed (Alexander et al 2000;Peterson et al 2001).…”

Section: Electronic Supplementary Materialsmentioning

confidence: 99%

Enhanced hyporheic exchange flow around woody debris does not increase nitrate reduction in a sandy streambed

et al. 2017

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Anthropogenic nitrogen pollution is a critical problem in freshwaters. Although riverbeds are known to attenuate nitrate, it is not known if large woody debris (LWD) can increase this ecosystem service through enhanced hyporheic exchange and streambed residence time. Over a year, we monitored the surface water and pore water chemistry at 200 points along a * 50 m reach of a lowland sandy stream with three natural LWD structures. We directly injected 15 N-nitrate at 108 locations within the top 1.5 m of the streambed to quantify in situ denitrification, anammox and dissimilatory nitrate reduction to ammonia, which, on average, contributed 85, 10 and 5% of total nitrate reduction, respectively. Total nitrate reducing activity ranged from 0 to 16 lM h -1 and was highest in the top 30 cm of the stream bed. Depth, ambient nitrate and water residence time explained 44% of the observed variation in nitrate reduction; fastest rates were associated with slow flow and shallow depths. In autumn, when the river was in spate, nitrate reduction (in situ and laboratory measures) was enhanced around the LWD compared with non-woody areas, but this was not seen in the spring and summer. Overall, there was no significant effect of LWD on nitrate reduction rates in surrounding streambed sediments, but higher pore water nitrate concentrations and shorter residence times, close to LWD, indicated enhanced delivery of surface water into the streambed under high flow. When hyporheic exchange is too strong, overall nitrate reduction is inhibited due to short flow-paths and associated high oxygen concentrations.

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Section: Electronic Supplementary Materialsmentioning

confidence: 99%

Enhanced hyporheic exchange flow around woody debris does not increase nitrate reduction in a sandy streambed

et al. 2017

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“…Consequently, the dynamic pattern of vertical hydraulic exchange exerts a strong influence on physical and chemical conditions such as temperature, oxygen concentrations and the residence time of water (Olsen & Townsend, 2003;Krause et al, 2011b). Surface water downwelling into subsurface sediments typically delivers oxygen and inputs of organic matter to hyporheic habitats, promoting aerobic microbial processes (Findlay et al, 1993;Pinay et al, 2015). In contrast, oxygen poor, nutrientrich water often enters the stream at upwelling locations (Grimm et al, 2007).…”

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confidence: 99%

Benthic and hyporheic macroinvertebrate distribution within the heads and tails of riffles during baseflow conditions

2017

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The distribution of lotic fauna is widely acknowledged to be patchy reflecting the interaction between biotic and abiotic factors. In an in situ field study, the distribution of benthic and hyporheic invertebrates in the heads (downwelling) and tails (upwelling) of riffles were examined during stable baseflow conditions. Riffle heads were found to contain a greater proportion of interstitial fine sediment than riffle tails. Significant differences in the composition of benthic communities were associated with the amount of fine sediment. Riffle tail habitats supported a greater abundance and diversity of invertebrates sensitive to fine sediment such as EPT taxa. Shredder feeding taxa were more abundant in riffle heads suggesting greater availability of organic matter. In contrast, no significant differences in the hyporheic community were recorded between riffle heads and tails. We hypothesise that clogging of hyporheic interstices with fine sediments may have resulted in the homogenisation of the invertebrate community by limiting faunal movement into the hyporheic zone at both the riffle heads and tails. The results suggest that vertical hydrological exchange significantly influences the distribution of fine sediment and macroinvertebrate communities at the riffle scale.

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“…We propose that the comparison of travel time from catchments from differing biomes could lead to a more systematic understanding of catchment behaviour and general theory. Because biogeochemistry is tightly linked to residence time, a better understanding of the travel time distributions will improve the assessment of nutrient removal capacity (Pinay et al, 2015), climate change impacts on stream chemistry (Abbott et al, 2015;Goode, 1996;McGuire et al, 2005) and exposure time (Ginn, 1999;Frei et al, this issue;Oldham et al, 2013).…”

Section: Temporal Variabilitymentioning

confidence: 99%

“…These hydrological parameters influence catchment biogeochemistry (Ocampo et al, 2006;Oldham et al, 2013;Pinay et al, 2015;Tetzlaff et al, 2007), further increasing their value as 4 indicators and predictors of catchment-scale water quality and chemistry. Because these parameters are of great general interest they feature prominently in the inputs and outputs of many models (e.g.…”

Section: Introductionmentioning

confidence: 99%

“…The mean transit time and whole stream residence time distribution are powerful metrics of catchment functioning, providing synoptic hydrological information such as water renewal time, heterogeneity of flowpaths, and overall water volume (Godsey et al, 2010;Hrachowitz et al, 2010; Marçais et al, 2015;McGuire and McDonnell, 2006;Van der Velde et al, 2012) . These hydrological parameters influence catchment biogeochemistry (Ocampo et al, 2006;Oldham et al, 2013;Pinay et al, 2015;Tetzlaff et al, 2007), further increasing their value as …”

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Constitution of a catchment virtual observatory for sharing flow and transport models outputs

Thomas

Rousseau-Gueutin

Kolbe

et al. 2016

Journal of Hydrology

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Accepted ManuscriptConstitution of a catchment virtual observatory for sharing flow and transport models outputs Zahra Thomas, Pauline Rousseau-Gueutin, Tamara Kolbe, Benjamin W. Abbott, Jean Marçais, Stefan Peiffer, Sven Frei, Kevin Bishop, Pascal Pichelin, Gilles Pinay, Jean-Raynald de Dreuzy PII:S0022-1694(16)30260-8 DOI:http://dx.doi.org/10.1016/j.jhydrol.2016.04.067 Reference:HYDROL 21237To appear in: Journal of HydrologyPlease cite this article as: Thomas, Z., Rousseau-Gueutin, P., Kolbe, T., Abbott, B.W., Marçais, J., Peiffer, S., Frei, S., Bishop, K., Pichelin, P., Pinay, G., de Dreuzy, J-R., Constitution of a catchment virtual observatory for sharing flow and transport models outputs, Journal of Hydrology (2016), doi: http://dx.doi.org/10.1016/j.jhydrol. 2016.04.067This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. The mean transit time and whole stream residence time distribution are powerful metrics of catchment functioning, providing synoptic hydrological information such as water renewal time, heterogeneity of flowpaths, and overall water volume (Godsey et al., 2010;Hrachowitz et al., 2010; Marçais et al., 2015;McGuire and McDonnell, 2006;Van der Velde et al., 2012) . These hydrological parameters influence catchment biogeochemistry (Ocampo et al., 2006;Oldham et al., 2013;Pinay et al., 2015;Tetzlaff et al., 2007), further increasing their value as Constitution of a catchment virtual observatory for sharing flow and transport modelsObservatory for sharing models outputs Thomas et al. 4 indicators and predictors of catchment-scale water quality and chemistry. Because these parameters are of great general interest they feature prominently in the inputs and outputs of many models (e.g. McGuire et al., 2005;Tetzlaff et al., 2009a (Bishop et al., 2008). Small catchments express a wide diversity of subsurface flow configurations (Eberts et al., 2012;Gburek and Folmar, 1999;Sophocleous, 2002;Winter, 1999) depending on geological and topographical structures, distribution and timing of recharge, characteristics of the vadose zone, and free surface dynamics of the underlying aquifer (Bresciani et al., 2014;Schumann et al., 2010;Freer et al., 2002;Montgomery and Dietrich, 1989;O'loughlin, 1981;Šimŭnek et al., 2003;Voeckler et al., 2014; Dages et al., 2009; de Vries and Simmers, 2002;Scanlon et al., 2002).Observatory for sharing models outputs Thomas et al. 6 Perhaps most importantly in regards to catchment hydrology, small catchments are a convenient and powerful experimental unit. Compared to large catchments, there are fewer processes influencing behaviour of small catchments and collecti...

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Upscaling Nitrogen Removal Capacity from Local Hotspots to Low Stream Orders’ Drainage Basins

Cited by 122 publications

References 147 publications

Enhanced hyporheic exchange flow around woody debris does not increase nitrate reduction in a sandy streambed

Enhanced hyporheic exchange flow around woody debris does not increase nitrate reduction in a sandy streambed

Benthic and hyporheic macroinvertebrate distribution within the heads and tails of riffles during baseflow conditions

Constitution of a catchment virtual observatory for sharing flow and transport models outputs

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