Gas dispersion in granular porous media under air-dry and wet conditions

Subsurface gaseous-phase transport is governed by three gas transport parameters: the air permeability coefficient (k(a)), gas diffusion coefficient (D(P)), and gas dispersion coefficient (D(H)). Among these, D(H) is the least understood due to hitherto limited research into the relationship between...

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Bibliographic Details
Published inSoil Science Society of America journal Vol. 76; no. 3; pp. 845 - 852
Main Authors Naveed, Muhammad, Hamamoto, Shoichiro, Kawamoto, Ken, Sakaki, Toshihiro, Takahashi, Manabu, Komatsu, Toshiko, Jonge, Lis Wollesen de, Lamandé, Mathieu, Moldrup, Per
Format Journal Article
LanguageEnglish
Published Madison, WI Soil Science Society of America 01.05.2012
The Soil Science Society of America, Inc
American Society of Agronomy
Subjects
Advection
Agronomy. Soil science and plant productions
air
Biological and medical sciences
bulk density
Diffusion coefficient
diffusivity
Earth sciences
Earth, ocean, space
equations
Exact sciences and technology
Fundamental and applied biological sciences. Psychology
glass
Moisture content
Particle shape
Particle size
particle size distribution
permeability
Permeability coefficient
Porosity
Porous media
prediction
sand
Soil columns
soil physical properties
Soil science
Soils
Surficial geology
water content
humidity
Soil science
air
Earth science
dispersion
porous media
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Summary:Subsurface gaseous-phase transport is governed by three gas transport parameters: the air permeability coefficient (k(a)), gas diffusion coefficient (D(P)), and gas dispersion coefficient (D(H)). Among these, D(H) is the least understood due to hitherto limited research into the relationship between gas dispersion and soil physical characteristics. In this study, a series of advection-dispersion experiments was performed on granular porous media to identify the effects of soil column dimensions (length and diameter), particle size and shape, dry bulk density, and moisture content on the magnitude of gas dispersion. Glass beads and various sands of different shapes (angular and rounded) with mean particle diameters (d(50)) ranging from 0.19 to 1.51 mm at both air-dry and variable moisture contents were used as granular porous media. Gas dispersion coefficients and gas dispersivities (α = D(H)/v, where v is the pore-gas velocity) were determined by fitting the advection-dispersion equation to the measured breakthrough curves. For all test conditions, D(H) increased linearly with v. The test results showed that neither soil column length nor diameter had significant effect on gas dispersivity. Under air-dry conditions, higher gas dispersivities were observed for media with wider particle size distribution and higher dry bulk density. The minor effect of particle shape on gas dispersivity was found under both air-dry and wet conditions. Under wet conditions, the variations in gas dispersivity were mainly controlled by the air-filled porosity. An empirical model was also proposed for the prediction of gas dispersivity in granular, unsaturated porous media.
Bibliography:http://dx.doi.org/10.2136/sssaj2011.0314
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ISSN:0361-5995
1435-0661
DOI:10.2136/sssaj2011.0314