Headwater gas exchange quantified from O<sub>2</sub> mass balances at the reach scale

Rovelli, Lorenzo; Attard, Karl M.; Heppell, Catherine M.; Binley, Andrew; Trimmer, Mark; Glud, Ronnie N.

doi:10.1002/lom3.10281

Cited by 9 publications

(29 citation statements)

References 88 publications

(135 reference statements)

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“…Given a benthic O 2 flux, it is then possible to create an oxygen budget from which gas exchange can be calculated (Rovelli et al, 2018). This method provides an indirect, but likely accurate measure of k, and enables estimating variation within a day, for example, from the effects of wind (Rovelli et al, 2018). These underwater eddy covariance methods can also directly estimate gas exchange (Berg & Pace, 2017).…”

Section: Eddy Covariance In Air or Watermentioning

confidence: 99%

“…Although predicting gas exchange for any one site using models is highly uncertain, the good news is that methods for estimating gas exchange within a site are becoming easier to conduct. New empirical methods with tracer gas additions (Hall & Madinger, 2018) underwater eddy covariance (Berg & Pace, 2017;Rovelli et al, 2018), and linkages to hydrodynamics (Lorke et al, 2019) will improve estimates at any one site. Modeling oxygen dynamics allows estimating k 600 for many streams with long time series of oxygen collected for water quality purposes.…”

Section: Estimates For a Particular Streammentioning

confidence: 99%

“…By stationing a threedimensional (3D) velocimeter and a rapid response O 2 sensor, one can measure benthic O 2 fluxes directly (Koopmans & Berg, 2015). Given a benthic O 2 flux, it is then possible to create an oxygen budget from which gas exchange can be calculated (Rovelli et al, 2018). This method provides an indirect, but likely accurate measure of k, and enables estimating variation within a day, for example, from the effects of wind (Rovelli et al, 2018).…”

Section: Eddy Covariance In Air or Watermentioning

confidence: 99%

“…Modeling approaches (Appling, Hall, et al, 2018;Holtgrieve, Schindler, Branch, & A'mar, 2010) use the gas exchangeinduced shape in the curve to evaluate K 600 separately from metabolism Elosegi, 2009;Genzoli & Hall, 2016;Izagirre, Agirre, Bermejo, Pozo, & Elosegi, 2008;Izagirre, Bermejo, Pozo, & Elosegi, 2007;Ulseth et al, 2017) but is not often compared to other methods (except see Aristegi et al, 2009). Rovelli et al (2018) found that the nighttime regression method overestimated K relative to their oxygen budget approach.…”

Section: Gas Exchange From Oxygen Time Seriesmentioning

confidence: 99%

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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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Section: Eddy Covariance In Air or Watermentioning

confidence: 99%

Section: Estimates For a Particular Streammentioning

confidence: 99%

Section: Eddy Covariance In Air or Watermentioning

confidence: 99%

Section: Gas Exchange From Oxygen Time Seriesmentioning

confidence: 99%

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Gas exchange in streams and rivers

Hall

Ulseth

2019

WIREs Water

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“…We confirmed modeled K using nighttime linear regression of dissolved oxygen (Hall & Hotchkiss, 2017, supporting information Figures S5 and S6). We found that the relationship between K-ER is lowest and potential for equifinality reduced when constraining K according to a K~Q relationship, compared to using air-water gas exchange scaled to a temperature of 20°C , as in Rovelli et al (2018); supporting information Figures S7 and S8). Additionally, we removed 30 days with K values below the 1% (<3.38 d −1 ) and above the 99% (>27.21 d −1 ) quantiles to further decrease the chances of using biased metabolism estimates in our P-Q analyses (Figure S6).…”

Section: Metabolism Estimatesmentioning

confidence: 93%

Coupling Concentration‐ and Process‐Discharge Relationships Integrates Water Chemistry and Metabolism in Streams

O'Donnell

Hotchkiss

2019

Water Resources Research

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Stream ecosystem processes, such as metabolism, are dynamically impacted by flow intensity.Therefore, without integrating ecosystem processes with water quality, we miss opportunities to develop frameworks to understand metabolic responses to changing flow. Flow simultaneously affects the material transport and biological opportunities for material transformation. Combining the strengths of ecohydrology and stream ecology to understand how flow variation alters ecosystem processes, we analyzed more than 5 years of water quality and stream metabolism data. We created segmented process-discharge (P-Q) relationships to examine how metabolism rates vary across discharge and compared them to concentration-discharge (C-Q) relationships to explore the dynamic effects of discharge on processes and physicochemical parameters. Within the segmented P-Q relationships, we found the behavior of ecosystem respiration (ER), gross primary production (GPP), and net ecosystem production (NEP) to be different at high and low flows with varying degrees of statistical significance, demonstrating the potential for divergent metabolic responses across changing flows. GPP declined with increasing discharge. The rate of ER declined with discharge initially but then became unchanging at higher flows. NEP reflected the divergent trends between ER and GPP, as the relationship of NEP to Q was flat at lower discharge and declined at higher flows. Interrelated physicochemical parameters and ecosystem processes, such as pH and NEP, had mirrored responses to discharge. Coupling analyses of flow, water quality, and metabolism offers a more complete picture of interrelated ecosystem processes, allowing for a better understanding of ecosystem response to the physical and chemical changes that occur across flows. Plain Language SummaryUnderstanding how stream microorganisms respond to changes in water flow is needed to improve the health of aquatic ecosystems. While high discharge is frequent when nutrients and pollutants are swept downstream, we lack information about how biology and water quality change during high flow. To examine water quality across flows, concentration-discharge relationships are often quantified. However, by only looking at how water quality changes as a function of flow, we miss a key piece of information: Life within the stream. Life within a stream influences and is influenced by water quality and flow. Here, we used 5 years of chemistry and flow data to calculate stream metabolism: The processes of photosynthesis and respiration by the life within a stream. To assess how water quality changes across flow, we (1) identified how stream metabolism changes across flow via process-discharge analyses and (2) compared concentration-discharge and process-discharge trends to discover how they influenced one another. We found that stream metabolism exhibited different responses across flows. Moreover, multiple concentration-discharge relationships had mirrored responses to associated process-discharge relationships. This study ultim...

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Aerobic methane synthesis and dynamics in a river water environment

Alowaifeer

Wang

Bothner

et al. 2023

Limnology & Oceanography

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Reports of aerobic biogenic methane (CH4) have generated new views about CH4 sources in nature. We examine this phenomenon in the free‐flowing Yellowstone river wherein CH4 concentrations were tracked as a function of environmental conditions, phototrophic microorganisms (using chlorophyll a, Chl a, as proxy), as well as targeted methylated amines known to be associated with this process. CH4 was positively correlated with temperature and Chl a, although diurnal measurements showed CH4 concentrations were greatest during the night and lowest during maximal solar irradiation. CH4 efflux from the river surface was greater in quiescent edge waters (71–94 μmol m−2 d) than from open flowing current (~ 57 μmol m−2 d). Attempts to increase flux by disturbing the benthic environment in the quiescent water directly below (~ 1.0 m deep) or at varying distances (0–5 m) upstream of the flux chamber failed to increase surface flux. Glycine betaine (GB), dimethylamine and methylamine (MMA) were observed throughout the summer‐long study, increasing during a period coinciding with a marked decline in Chl a, suggesting a lytic event led to their release; however, this did not correspond to increased CH4 concentrations. Spiking river water with GB or MMA yielded significantly greater CH4 than nonspiked controls, illustrating the metabolic potential of the river microbiome. In summary, this study provides evidence that: (1) phototrophic microorganisms are involved in CH4 synthesis in a river environment; (2) the river microbiome possesses the metabolic potential to convert methylated amines to CH4; and (3) river CH4 concentrations are dynamic diurnally as well as during the summer active months.

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Headwater gas exchange quantified from O₂ mass balances at the reach scale

Cited by 9 publications

References 88 publications

Gas exchange in streams and rivers

Gas exchange in streams and rivers

Coupling Concentration‐ and Process‐Discharge Relationships Integrates Water Chemistry and Metabolism in Streams

Aerobic methane synthesis and dynamics in a river water environment

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Headwater gas exchange quantified from O2 mass balances at the reach scale

Cited by 9 publications

References 88 publications

Gas exchange in streams and rivers

Gas exchange in streams and rivers

Coupling Concentration‐ and Process‐Discharge Relationships Integrates Water Chemistry and Metabolism in Streams

Aerobic methane synthesis and dynamics in a river water environment

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Product

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Headwater gas exchange quantified from O₂ mass balances at the reach scale