On Factors Influencing Air‐Water Gas Exchange in Emergent Wetlands

Ho, David T.; Engel, V.; Ferrón, Sara; Hickman, Benjamin; Choi, Jay; Harvey, J. W.

doi:10.1002/2017jg004299

Cited by 25 publications

(31 citation statements)

References 46 publications

(75 reference statements)

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“…Higher night‐time fluxes may also occur due to convective overturning of the water column (Poindexter et al ). Our estimated convection rate (13.6%) was within range of wetland convection studies of Ho et al (), who found that convection contributed from 14% to 50% of the measured gas exchange in shallow sloughs within the Everglades, U.S.A., and Poindexter et al (), who showed convection was responsible for 32% of annual wetland emissions from a marsh in northern California, U.S.A. Our somewhat lower convection estimates may be related to the high coverage of lilies during C1 reducing the magnitude of the net solar radiation daily balance.…”

Section: Discussionsupporting

confidence: 82%

“…To estimate the relative importance of night‐time convection as a wetland CH 4 transport pathway, we utilized time series temperature data from C1 to estimate the convection gas transfer velocity ( k 600convection ) with the equation from Ho et al ():

k_{600 convection} = {(- q)}^{1 / 4} ((), - 1.5033 + 2.0913 normal\times T^{0.29793}) {(600 / \Pr)}^{- 2 / 3} for q < 0

where q is the net heat flux, T is the temperature between 6°C and 40°C, and Pr is the Prandtl number at T . By then applying k 600convection to our time series CH 4 data, we could then estimate the night‐time air–water CH 4 convection driven fluxes and determine the proportionate role of convection to our average C1 night‐time chamber flux measurements.…”

Section: Methodsmentioning

confidence: 99%

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Wetland methane emissions dominated by plant‐mediated fluxes: Contrasting emissions pathways and seasons within a shallow freshwater subtropical wetland

Jeffrey

Maher

Johnston

et al. 2019

Limnology & Oceanography

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Wetlands represent the largest natural source of methane; however, very few studies have simultaneously quantified the three main atmospheric flux pathways (i.e., diffusive, ebullition, and plant‐mediated). Unlike better‐studied northern hemisphere systems, many Australian subtropical wetlands undergo extreme wet/dry oscillations, which may strongly impact methane dynamics. We assessed diurnal methane emissions of multiple pathways during three distinct seasonal events within an Australian freshwater wetland. Six‐fold higher methane emissions occurred during summer compared to autumn floods (which followed an extensive dry‐period) and winter/cool conditions. Over three seasons, diffusion represented the highest average areal fluxes (25.9 ± 73.2 mmol m−2 d−1) but were within range of fluxes through water lily aerenchyma (20.8 ± 41.5 mmol m−2 d−1). Average ebullition rates were 5.5 ± 9.7 mmol m−2 d−1. Water column CH4 displayed high spatiotemporal variability, ranging from 55.0 to 253.5 μmol L−1. Time series δ13C–CH4 isotope measurements revealed an oxidation fraction of ~ 15% at night‐time and ~ 36% during day‐time, and night‐time diffusive fluxes were consistently ~ three‐fold higher than day‐time fluxes. By aggregating seasons and weighting for changes in lily coverage, plant‐mediated fluxes accounted for ~ 59% of the annual methane emissions, whereas ebullition and diffusion each accounted for ~ 20%. The up‐scaled annual area‐weighted wetland methane flux (combined pathways) was 27.3 ± 36.7 mmol m−2 d−1. We contend that water lilies (Nymphaea sp.) are the significant carbon source, mediator, and conduit for methane fluxes in this system, and the extremely large seasonal variability of methane emissions reflect dynamic redox oscillations driven by oscillating wet and dry conditions.

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Section: Discussionsupporting

confidence: 82%

k_{600 convection} = {(- q)}^{1 / 4} ((), - 1.5033 + 2.0913 normal\times T^{0.29793}) {(600 / \Pr)}^{- 2 / 3} for q < 0

Section: Methodsmentioning

confidence: 99%

Wetland methane emissions dominated by plant‐mediated fluxes: Contrasting emissions pathways and seasons within a shallow freshwater subtropical wetland

Jeffrey

Maher

Johnston

et al. 2019

Limnology & Oceanography

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“…Measured ε and buoyancy flux predicted from hourly temperature change, β T , were similar under cooling (Figure 3). This similarity implies that ε and k 600 can be computed for other sites from temperature change when β < 0, as computed previously for shallow herbaceous wetlands (Ho et al, 2018;Poindexter et al, 2016;Poindexter & Variano, 2013). The lower measured values of ε during heating under calm conditions are to be expected as the depth of the measurement volume of the ADV was within the stratified diurnal thermocline rather than within an actively mixing layer.…”

Section: Discussionsupporting

confidence: 73%

“…Flux, F = k (C w -C eq ), where k is gas transfer velocity, C w is concentration in the water, and C eq is concentration in the water at equilibrium with the atmosphere. In the SRM, k 600 = c 1 (ε·ν) 1/4 ·Sc −n where k 600 is the gas transfer coefficient normalized to CO 2 at 20°C, ε is rate of dissipation of turbulent kinetic energy, ν is kinematic viscosity, Sc is the Schmidt number, n is −1/2 with variability dependent on extent of surface films (Katul et al, 2018) but see Ho et al (2018), and coefficient c 1 is~0.5 (Katul et al, 2018;Lamont & Scott, 1970;Zappa et al, 2007) (See SI S.1.10). Rates of dissipation of turbulent kinetic energy can be obtained by direct measurements (Gålfalk et al, 2013;MacIntyre et al, 2018;Tedford et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Turbulence and Gas Transfer Velocities in Sheltered Flooded Forests of the Amazon Basin

MacIntyre

Amaral

Barbosa

et al. 2019

Geophysical Research Letters

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Seasonally flooded forests along tropical rivers cover extensive areas, yet the processes driving air‐water exchanges of radiatively active gases are uncertain. To quantify the controls on gas transfer velocities, we combined measurements of water‐column temperature, meteorology in the forest and adjacent open water, turbulence with an acoustic Doppler velocimeter, gas concentrations, and fluxes with floating chambers. Under cooling, measured turbulence, quantified as the rate of dissipation of turbulent kinetic energy (ε), was similar to buoyancy flux computed from the surface energy budget, indicating convection dominated turbulence production. Under heating, turbulence was suppressed unless winds in the adjacent open water exceeded 1 m/s. Gas transfer velocities obtained from chamber measurements ranged from 1 to 5 cm/hr and were similar to or slightly less than predicted using a turbulence‐based surface renewal model computed with measured ε and ε predicted from wind and cooling.

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“…However, it remains likely that factors other than wind-or convection-driven turbulence affected k 600 and may have played a role in increased nighttime k 600 . One important such factor that was not accounted for in this study was bottom-driven turbulence, which has been shown to at times significantly enhance gas transfer velocity, particularly in shallow estuaries (Ho et al, 2016(Ho et al, , 2018Maurice et al, 2017;Raymond & Cole, 2001;Rosentreter et al, 2017;Zappa et al, 2007). Because the NRE is quite shallow (average depth <2 m), it is plausible that bottom-driven turbulence may have played an important role in enhancing k. While measurements related to water turbulence or velocity were not possible during the present study, such an investigation into bottom-driven turbulence remains an important avenue for future research.…”

Section: Effects Of Convection On Gas Transfer Velocitymentioning

confidence: 97%

Parameterizing Air‐Water Gas Exchange in the Shallow, Microtidal New River Estuary

2019

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Estuarine CO2 emissions are important components of regional and global carbon budgets, but assessments of this flux are plagued by uncertainties associated with gas transfer velocity (k) parameterization. We combined direct eddy covariance measurements of CO2 flux with waterside pCO2 determinations to generate more reliable k parameterizations for use in small estuaries. When all data were aggregated, k was described well by a linear relationship with wind speed (U10), in a manner consistent with prior open ocean and estuarine k parameterizations. However, k was significantly greater at night and under low wind speed, and nighttime k was best predicted by a parabolic, rather than linear, relationship with U10. We explored the effect of waterside thermal convection but found only a weak correlation between convective scale and k. Hence, while convective forcing may be important at times, it appears that factors besides waterside thermal convection were likely responsible for the bulk of the observed nighttime enhancement in k. Regardless of source, we show that these day‐night differences in k should be accounted for when CO2 emissions are assessed over short time scales or when pCO2 is constant and U10 varies. On the other hand, when temporal variability in pCO2 is large, it exerts greater control over CO2 fluxes than does k parameterization. In these cases, the use of a single k value or a simple linear relationship with U10 is often sufficient. This study provides important guidance for k parameterization in shallow or microtidal estuaries, especially when diel processes are considered.

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On Factors Influencing Air‐Water Gas Exchange in Emergent Wetlands

Cited by 25 publications

References 46 publications

Wetland methane emissions dominated by plant‐mediated fluxes: Contrasting emissions pathways and seasons within a shallow freshwater subtropical wetland

Wetland methane emissions dominated by plant‐mediated fluxes: Contrasting emissions pathways and seasons within a shallow freshwater subtropical wetland

Turbulence and Gas Transfer Velocities in Sheltered Flooded Forests of the Amazon Basin

Parameterizing Air‐Water Gas Exchange in the Shallow, Microtidal New River Estuary

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