A Structure Function Model Recovers the Many Formulations for Air‐Water Gas Transfer Velocity

Katul, Gabriel G.; Mammarella, Ivan; Grönholm, Tiia; Vesala, Timo

doi:10.1029/2018wr022731

Cited by 17 publications

(19 citation statements)

References 112 publications

(228 reference statements)

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“…Because darkened floating chambers could have biased daytime CO 2 emissions by limiting photosynthetic uptake, we instead estimated CO 2 fluxes using pCO 2 from water samples (2015–2017) and a boundary layer model:

F = k ((), C_{aq} - C_{italicair, italiceq}),

where k is the gas transfer velocity and C aq − C air , eq represents the concentration difference between the water in the boundary layer and at equilibrium with the air above, determined from weekly measurements of surface water CO 2 concentrations (Figure ) and assuming an atmospheric mixing ratio of 400 ppm. We determined k with a surface renewal model (Lamont & Scott, ):

k = c_{1} {(italicεν)}^{\frac{1}{4}} {Sc}^{- \frac{1}{2}},

where c 1 is a scaling parameter determined to be ∽0.4 on theoretical grounds (Katul et al, ; Lamont & Scott, ) and from analysis of multiple experiments including physical measurements of turbulence and eddy covariance (Zappa et al, ), ν is the kinematic viscosity, Sc is the Schmidt number for CO 2 (Jähne et al, ), and ε is the dissipation rate of turbulent kinetic energy, which is driven by wind shear ( u * w ) and the buoyancy flux under cooling ( β ) (Tedford et al, ):

ε = ({, \begin{matrix} 0.56 u_{* w}^{3} / κz + 0.77 β if β > 0 \\ 0.6 u_{* w}^{3} / κz if β \leq 0 \end{matrix}) .

…”

Section: Methodsmentioning

confidence: 99%

“…where c 1 is a scaling parameter determined to be ∽0.4 on theoretical grounds (Katul et al, 2018;Lamont & Scott, 1970) and from analysis of multiple experiments including physical measurements of turbulence and eddy covariance (Zappa et al, 2007), ν is the kinematic viscosity, Sc is the Schmidt number for CO 2 (Jähne et al, 1987), and ε is the dissipation rate of turbulent kinetic energy, which is driven by wind shear (u *w ) and the buoyancy flux under cooling (β) (Tedford et al, 2014):…”

Section: Estimation Of the Ice-free Co 2 Flux With A Boundary Layer Mmentioning

confidence: 99%

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Climate‐Sensitive Controls on Large Spring Emissions of CH₄ and CO₂ From Northern Lakes

et al. 2019

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Northern lakes are important sources of the climate forcing trace gases methane (CH4) and carbon dioxide (CO2). A substantial portion of lakes' annual emissions can take place immediately after ice melt in spring. The drivers of these fluxes are neither well constrained nor fully understood. We present a detailed carbon gas budget for three subarctic lakes, using 6 years of eddy covariance and 9 years of manual flux measurements. We combine measurements of temperature, dissolved oxygen, and CH4 stable isotopologues to quantify functional relationships between carbon gas production and conversion, energy inputs, and the redox regime. Spring emissions were regulated by the availability of oxygen in winter, rather than temperature as during ice‐free conditions. Under‐ice storage increased predictably with ice‐cover duration, and CH4 accumulation rates (25 ± 2 mg CH4‐C·m−2·day−1) exceeded summer emissions (19 ± 1 mg CH4‐C·m−2·day−1). The seasonally ice‐covered lakes emitted 26–59% of the annual CH4 flux and 15–30% of the annual CO2 flux at ice‐off. Reduced spring emissions were associated with winter snowmelt events, which can transport water downstream and oxygenate the water column. Stable isotopes indicate that 64–96% of accumulated CH4 escaped oxidation, implying that a considerable portion of the dissolved gases produced over winter may evade to the atmosphere.

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F = k ((), C_{aq} - C_{italicair, italiceq}),

k = c_{1} {(italicεν)}^{\frac{1}{4}} {Sc}^{- \frac{1}{2}},

ε = ({, \begin{matrix} 0.56 u_{* w}^{3} / κz + 0.77 β if β > 0 \\ 0.6 u_{* w}^{3} / κz if β \leq 0 \end{matrix}) .

…”

Section: Methodsmentioning

confidence: 99%

Section: Estimation Of the Ice-free Co 2 Flux With A Boundary Layer Mmentioning

confidence: 99%

Climate‐Sensitive Controls on Large Spring Emissions of CH₄ and CO₂ From Northern Lakes

et al. 2019

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“…Given that gas flux (F) is the product of a gas exchange velocity and concentration gradient, for example, Equation 1, much of the variation in estimates of F stem from variation in k. A large and old body of theory guides understanding of controls on k (Bennett & Rathbun, 1972), and this theory is advancing today (e.g., Katul, Mammarella, Grönholm, & Vesala, 2018). Here we provide a general overview.…”

Section: Physical Basis Of Variation In Gas Exchangementioning

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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“…The results suggest that the ‘−1/4’ scaling law is an outcome of the Kolmogorov microscale and the associated time scale, while the viscous corrections only alter the scaling of F E with respect to Sc but not u * (G. Katul & Liu, ). Revisions to surface renewal theories that account for large eddies have been proposed and reviewed elsewhere (G. Katul, Mammarella, Grönholm, & Vesala, ). These theories confirm that the similarity constant A E in Equation 39 vary as power‐law with a Reynolds number, a finding that has been confirmed by DNS and several laboratory studies (G. Katul et al, ).…”

Section: Further Readingmentioning

confidence: 99%

A primer on turbulence in hydrology and hydraulics: The power of dimensional analysis

Katul

Manes

2019

WIREs Water

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The apparent random swirling motion of water is labeled “turbulence,” which is a pervasive state of the flow in many hydrological and hydraulic transport phenomena. Water flow in a turbulent state can be described by the momentum conservation equations known as the Navier–Stokes (NS) equations. Solving these equations numerically or in some approximated form remains a daunting task in applications involving natural systems thereby prompting interest in alternative approaches. The apparent randomness of swirling motion encodes order that may be profitably used to describe water movement in natural systems. The goal of this primer is to illustrate the use of a technique that links aspects of this ordered state to conveyance and transport laws. This technique is “dimensional analysis”, which can unpack much of the complications associated with turbulence into surprisingly simplified expressions. The use of this technique to describing water movement in streams as well as water vapor movement in the atmosphere is featured. Particular attention is paid to bulk expressions that have received support from a large body of experiments such as flow‐resistance formulae, the Prandtl‐von Karman log‐law describing the mean velocity shape, Monin‐Obukhov similarity theory that corrects the mean velocity shape for thermal stratification, and evaporation from rough surfaces. These applications illustrate how dimensional analysis offers a pragmatic approach to problem solving in sciences and engineering. This article is categorized under: Science of Water > Methods Science of Water > Hydrological Processes

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A Structure Function Model Recovers the Many Formulations for Air‐Water Gas Transfer Velocity

Cited by 17 publications

References 112 publications

Climate‐Sensitive Controls on Large Spring Emissions of CH₄ and CO₂ From Northern Lakes

Climate‐Sensitive Controls on Large Spring Emissions of CH₄ and CO₂ From Northern Lakes

Gas exchange in streams and rivers

A primer on turbulence in hydrology and hydraulics: The power of dimensional analysis

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A Structure Function Model Recovers the Many Formulations for Air‐Water Gas Transfer Velocity

Cited by 17 publications

References 112 publications

Climate‐Sensitive Controls on Large Spring Emissions of CH4 and CO2 From Northern Lakes

Climate‐Sensitive Controls on Large Spring Emissions of CH4 and CO2 From Northern Lakes

Gas exchange in streams and rivers

A primer on turbulence in hydrology and hydraulics: The power of dimensional analysis

Contact Info

Product

Resources

About

Climate‐Sensitive Controls on Large Spring Emissions of CH₄ and CO₂ From Northern Lakes

Climate‐Sensitive Controls on Large Spring Emissions of CH₄ and CO₂ From Northern Lakes