A model investigation of turbulence‐driven pressure‐pumping effects on the rate of diffusion of CO2, N2O, and CH4 through layered snowpacks

Massman, W. J.; Sommerfeld, R. A.; Mosier, A. R.; Zeller, Karl; Hehn, Ted; Rochelle, S. G.

doi:10.1029/97jd00844

Cited by 131 publications

(153 citation statements)

References 24 publications

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“…In addition, an influence of air pressure fluctuations on soil gas transport was observed [2,[9][10][11]. This influence is referred to as turbulence-induced "pressure pumping" and has attracted great interest in recent years [8,[12][13][14][15][16][17][18][19][20]. Results from present research suggest that soil gas transport is enhanced up to 100% by air pressure fluctuations induced by airflow, dependent on the investigated soil [18,19,21].…”

Section: Introductionmentioning

confidence: 53%

Analysis of Air Pressure Fluctuations and Topsoil Gas Concentrations within a Scots Pine Forest

et al. 2016

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High-precision differential air pressure measurements were conducted in the below-canopy space of a Scots pine forest and in the forest soil to investigate small air pressure fluctuations and their effect on soil gas flux. In addition to air pressure measurements, tracer gas concentration in the soil and airflow characteristics above and below the canopy were measured. Results suggest that air pressure fluctuations in the frequency range of 0.01 Hz-0.1 Hz are strongly dependent on abovecanopy wind speed. While amplitudes of the observed air pressure fluctuations (<10 Pa) increase significantly with increasing above-canopy wind speed, the periods decrease significantly with increasing above-canopy wind speed. These air pressure fluctuations are associated with the pressure-pumping effect in the soil. A pressure-pumping coefficient was defined, which describes the strength of the pressure-pumping effect. During the measurement period, pressure-pumping coefficients up to 0.44 Pa·s −1 were found. The dependence of the pressure-pumping coefficient on mean above-canopy wind speed can be described well with a polynomial fit of second degree. The knowledge of this relation simplifies the quantification of the pressure-pumping effect in a Scots pine forest considerably, since only the mean above-canopy wind speed has to be measured. In addition, empirical modeling revealed that the pressure-pumping coefficient explains the largest fraction of the variance of tracer gas concentration in the topsoil.

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Section: Introductionmentioning

confidence: 53%

Analysis of Air Pressure Fluctuations and Topsoil Gas Concentrations within a Scots Pine Forest

et al. 2016

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“…venting the soil surface (according to Bernouilli's equation) or turbulence above the soil surface. Typical air pressure fluctuations are of the order of 10 Pa (Maier et al, 2012;Massman et al, 1997). Pressure fluctuations can also result from nonhydrostatic density fluctuations caused by a change in the air composition with gas species of different molar mass as air or by temperature gradients, but the resulting flux is significant only in highly permeable (i.e.…”

Section: Advective Fluxesmentioning

confidence: 99%

“…When averaged over a long enough timescale (> 1 h) the advective flux starts to become negligible compared to the diffusive flux (e.g. Massman et al, 1997). Integration timescales of a few minutes were already assumed to allow liquid-vapour equilibration in Eq.…”

Section: Advective Fluxesmentioning

confidence: 99%

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A new mechanistic framework to predict OCS fluxes from soils

Ogée¹,

et al. 2016

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Abstract.Estimates of photosynthetic and respiratory fluxes at large scales are needed to improve our predictions of the current and future global CO 2 cycle. Carbonyl sulfide (OCS) is the most abundant sulfur gas in the atmosphere and has been proposed as a new tracer of photosynthetic gross primary productivity (GPP), as the uptake of OCS from the atmosphere is dominated by the activity of carbonic anhydrase (CA), an enzyme abundant in leaves that also catalyses CO 2 hydration during photosynthesis. However soils also exchange OCS with the atmosphere, which complicates the retrieval of GPP from atmospheric budgets. Indeed soils can take up large amounts of OCS from the atmosphere as soil microorganisms also contain CA, and OCS emissions from soils have been reported in agricultural fields or anoxic soils. To date no mechanistic framework exists to describe this exchange of OCS between soils and the atmosphere, but empirical results, once upscaled to the global scale, indicate that OCS consumption by soils dominates OCS emission and its contribution to the atmospheric budget is large, at about one third of the OCS uptake by vegetation, also with a large uncertainty. Here, we propose a new mechanistic model of the exchange of OCS between soils and the atmosphere that builds on our knowledge of soil CA activity from CO 2 oxygen isotopes. In this model the OCS soil budget is described by a first-order reaction-diffusion-production equation, assuming that the hydrolysis of OCS by CA is total and irreversible. Using this model we are able to explain the observed presence of an optimum temperature for soil OCS uptake and show how this optimum can shift to cooler temperatures in the presence of soil OCS emission. Our model can also explain the observed optimum with soil moisture content previously described in the literature as a result of diffusional constraints on OCS hydrolysis. These diffusional constraints are also responsible for the response of OCS uptake to soil weight and depth observed previously. In order to simulate the exact OCS uptake rates and patterns observed on several soils collected from a range of biomes, different CA activities had to be invoked in each soil type, coherent with expected physiological levels of CA in soil microbes and with CA activities derived from CO 2 isotope exchange measurements, given the differences in affinity of CA for both trace gases. Our model can be used to help upscale laboratory measurements to the plot or the region. Several suggestions are given for future experiments in order to test the model further and allow a better constraint on the large-scale OCS fluxes from both oxic and anoxic soils.

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“…[21] The potential effects of the so-called ''turbulent pumping'' [Kimball and Lemon, 1971;Massman et al, 1997] on mass exchange were not considered in this study. Such turbulence-driven pressure pumping effects are minor in wet porous surfaces with small water-filled pores, as both wetness and small pore size act to dampen convection into the porous medium.…”

Section: Evaporation From a Smooth Porous Surfacementioning

confidence: 99%

Evaporation from porous surfaces into turbulent airflows: Coupling eddy characteristics with pore scale vapor diffusion

Haghighi

2013

Water Resour. Res.

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.[1] Evaporative fluxes from terrestrial porous surfaces are determined by interplay between internal capillary and diffusive transport, energy input, and mass exchange across the landair interface. Turbulent airflows near the Earth's surface introduce complex boundary conditions that affect vapor, heat, and momentum exchange rates with the atmosphere. The impact of turbulent airflow on evaporation from porous surfaces was quantified using surface renewal theory coupled with a physically based pore scale model for vapor transfer from partially wet surfaces to individual eddies. The model considers diffusive vapor exchange with individual eddies interacting intermittently with a drying surface to quantify mean surface evaporative fluxes. The model captures nonlinearities between surface water content and evaporation flux during drying of porous surfaces, yielding close agreement with experimental results. This new diffusion-turbulence evaporation model provides a basic building block for improving estimation of field-scale evaporative fluxes from drying soil surfaces under natural airflows.Citation: Haghighi, E., and D. Or (2013), Evaporation from porous surfaces into turbulent airflows: Coupling eddy characteristics with pore scale vapor diffusion, Water Resour. Res., 49,[8432][8433][8434][8435][8436][8437][8438][8439][8440][8441][8442]

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A model investigation of turbulence‐driven pressure‐pumping effects on the rate of diffusion of CO₂, N₂O, and CH₄ through layered snowpacks

Cited by 131 publications

References 24 publications

Analysis of Air Pressure Fluctuations and Topsoil Gas Concentrations within a Scots Pine Forest

Analysis of Air Pressure Fluctuations and Topsoil Gas Concentrations within a Scots Pine Forest

A new mechanistic framework to predict OCS fluxes from soils

Evaporation from porous surfaces into turbulent airflows: Coupling eddy characteristics with pore scale vapor diffusion

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