Balancing watershed nitrogen budgets: accounting for biogenic gases in streams

Gardner, John R.; Fisher, Thomas; Jordan, Thomas E.; Knee, Karen L.

doi:10.1007/s10533-015-0177-1

Cited by 45 publications

(51 citation statements)

References 86 publications

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“…Using separate microcosm estimates of ER and DN to partition their relative contributions, our results show that the water column may be responsible for a substantial portion of reach‐scale ER in some rivers, and a portion of water column N removal can be attributed to denitrification which permanently removes NO 3 − ‐N from the ecosystem. We note that the microcosm approach excludes the influence of groundwater on sediment DN, which can be substantial in small streams [ Gardner et al ., ] but likely less influential in our study rivers. Incorporating these findings into watershed models focused on N uptake or retention [ Alexander et al ., ; Wollheim et al ., ; Ye et al ., ] will improve the accuracy and mechanistic basis of these models.…”

Section: Discussionmentioning

confidence: 99%

“…We acknowledge that groundwater can also be out of equilibrium with the atmosphere due to groundwater flowing through soils at different temperatures than the river. Estimates of the groundwater contribution to excess N 2 and Ar can be made using 222 Rn to separate in‐stream and groundwater contributions to N 2 production, and recent research has shown that groundwater can make significant contributions to excess N 2 in headwater streams [ Gardner et al ., ]. We were unable to separate these contributions with our data, but we assumed that the importance of groundwater contributions to N 2 production decreases with increasing stream size, as has been shown for CO 2 [ Hotchkiss et al ., ].…”

Section: Methodsmentioning

confidence: 99%

“…Additionally, a portion of N 2 found in streams may come from groundwater inflows [Gardner et al, 2016], potentially explaining differences between microcosm and open-channel approaches in the Tippecanoe R, but the contribution of groundwater to excess N 2 in the Tippecanoe R should be minimal compared to headwater streams. In the future, the analysis of a second gas tracer, such as 222 Rn [Gardner et al, 2016], would allow for assessing the groundwater contribution to riverine N 2 production. It is unclear why Journal of Geophysical Research: Biogeosciences 10.1002/2015JG003261 denitrification estimates made using 15 N tracer additions tend to be lower than other reach-scale estimates (Figure 8), but one potential reason could be that the 15 N-NO 3 À additions do not include coupled nitrification-denitrification, which may be particularly important in streams with NO 3 À -N concentrations <300 μg L À1 , thus underestimating denitrification rates as a whole [Mulholland et al, 2008].…”

Section: Comparisons To Other Aquatic Ecosystemsmentioning

confidence: 99%

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Sediment, water column, and open‐channel denitrification in rivers measured using membrane‐inlet mass spectrometry

et al. 2016

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Riverine biogeochemical processes are understudied relative to headwaters, and reach-scale processes in rivers reflect both the water column and sediment. Denitrification in streams is difficult to measure, and is often assumed to occur only in sediment, but the water column is potentially important in rivers. Dissolved nitrogen (N) gas flux (as dinitrogen (N 2 )) and open-channel N 2 exchange methods avoid many of the artificial conditions and expenses of common denitrification methods like acetylene block and 15 N-tracer techniques. We used membrane-inlet mass spectrometry and microcosm incubations to quantify net N 2 and oxygen flux from the sediment and water column of five Midwestern rivers spanning a land use gradient. Sediment and water column denitrification ranged from below detection to 1.8 mg N m À2 h À1 and from below detection to 4.9 mg N m À2 h À1 , respectively. Water column activity was variable across rivers, accounting for 0-85% of combined microcosm denitrification and 39-85% of combined microcosm respiration. Finally, we estimated reach-scale denitrification at one Midwestern river using a diel, open-channel N 2 exchange approach based on reach-scale metabolism methods, providing an integrative estimate of riverine denitrification. Reach-scale denitrification was 8.8 mg N m À2 h À1 (95% credible interval: 7.8-9.7 mg N m À2 h À1 ), higher than combined sediment and water column microcosm estimates from the same river (4.3 mg N m À2 h À1 ) and other estimates of reach-scale denitrification from streams. Our denitrification estimates, which span habitats and spatial scales, suggest that rivers can remove N via denitrification at equivalent or higher rates than headwater streams.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Comparisons To Other Aquatic Ecosystemsmentioning

confidence: 99%

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Sediment, water column, and open‐channel denitrification in rivers measured using membrane‐inlet mass spectrometry

et al. 2016

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“…It is necessary to know gas exchange using this method, even though the net flux of O 2 between stream and air is of little interest relative to the biological fluxes of O 2 in the stream. This method has been extended to other bioreactive gases, such as N 2 (Baulch, Venkiteswaran, Dillon, & Maranger, 2010;Gardner, Fisher, Jordan, & Knee, 2016). The second area of research interest is the source of streams as greenhouse gases to the atmosphere (Butman & Raymond, 2011;Raymond et al, 2013;Stanley et al, 2016), where gas exchange is needed to estimate gas flux following Equation 1.…”

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confidence: 99%

Gas exchange in streams and rivers

Hall

Ulseth

2019

WIREs Water

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Gas exchange across the air–water boundary of streams and rivers is a globally large biogeochemical flux. Gas exchange depends on the solubility of the gas of interest, the gas concentrations of the air and water, and the gas exchange velocity (k), usually normalized to a Schmidt number of 600, referred to as k600. Gas exchange velocity is of intense research interest because it is problematic to estimate, is highly spatially variable, and has high prediction error. Theory dictates that molecular diffusivity and turbulence drives variation in k600 in flowing waters. We measure k600 via several methods from direct measures, gas tracer experiments, to modeling of diel changes in dissolved gas concentrations. Many estimates of k600 show that surface turbulence explains variation in k600 leading to predictive models based upon geomorphic and hydraulic variables. These variables include stream channel slope and stream flow velocity, the product of which, is proportional to the energy dissipation rate in streams and rivers. These empirical models provide understanding of the controls on k600, yet high residual variation in k600 show that these simple models are insufficient for predicting individual locations. The most appropriate method to estimate gas exchange depends on the scientific question along with the characteristics of the study sites. We provide a decision tree for selecting the best method to estimate k600 for individual river reaches to scaling to river networks. This article is categorized under: Water and Life > Nature of Freshwater Ecosystems Science of Water > Water Quality Water and Life > Methods

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“…denitrified N 2 ) emitted in bubbles is that the fate of anthropogenic N will appear to be uncertain [13] [14] because nitrogen will seem to be "missing", in other words, not enough N output will be found to balance riverine N inputs and outputs. Several studies observed such imbalances [1] [11] [15]- [22].…”

Section: Introductionmentioning

confidence: 99%

An Empirical Model for Dinitrogen Gas Emission from Inland Waters

Sikar¹,

Santos²,

Santos³

2019

ACS

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The motivation to calculate this empirical model resulted from often observing-at the time disconcerting-excess dinitrogen gas (N 2 concentration > background concentration) in bubble-gas emission samples, collected primarily for the purpose of carbon budget research, from Brazilian rivers and reservoirs sampled during roughly 100 field surveys lasting 4 days each on average and executed between years 2000 and 2012. We model the (serendipitously) measured dinitrogen gas above environmental concentration (N 2 aec) escaping in bubbles from Brazilian rivers as a function of dissolved nitrogen (N) in water. To this model, we mathematically add a pre-existing model of diffusively emitted denitrified dinitrogen (also as a function of dissolved N) from streams in the United States of America (USA). The resulting model predicts denitrified dinitrogen water-air emission from inland waters in the USA, China and Germany.

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Balancing watershed nitrogen budgets: accounting for biogenic gases in streams

Cited by 45 publications

References 86 publications

Sediment, water column, and open‐channel denitrification in rivers measured using membrane‐inlet mass spectrometry

Sediment, water column, and open‐channel denitrification in rivers measured using membrane‐inlet mass spectrometry

Gas exchange in streams and rivers

An Empirical Model for Dinitrogen Gas Emission from Inland Waters

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