Ion Diffusion Within Water Films in Unsaturated Porous Media

Diffusion is important in controlling local solute transport and reactions in unsaturated soils and geologic formations. Although it is commonly assumed that thinning of water films controls solute diffusion at low water contents, transport under these conditions is not well understood. We conducted...

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Bibliographic Details
Published in:Environmental science & technology 2017-04, Vol.51 (8), p.4338-4346
Main Authors: Tokunaga, Tetsu K, Finsterle, Stefan, Kim, Yongman, Wan, Jiamin, Lanzirotti, Antonio, Newville, Matthew
Format: Article
Language:English
Subjects:
Desaturation
Diffusion
Film thickness
Geologic formations
Grain
Impedance
Ion diffusion
Ions
Porosity
Porous materials
Porous media
Quartz
Rubidium
Saturation
Silicon Dioxide
Solute transport
Synchrotron radiation
Synchrotrons
Thinning
Tortuosity
Unsaturated soils
Water
Water film
Water Movements
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Summary:Diffusion is important in controlling local solute transport and reactions in unsaturated soils and geologic formations. Although it is commonly assumed that thinning of water films controls solute diffusion at low water contents, transport under these conditions is not well understood. We conducted experiments in quartz sands at low volumetric water contents (θ) to quantify ion diffusion within adsorbed films. At the lowest water contents, we employed fixed relative humidities to control water films at nm thicknesses. Diffusion profiles for Rb+ and Br– in unsaturated sand packs were measured with a synchrotron X-ray microprobe, and inverse modeling was used to determine effective diffusion coefficients, D e, as low as ∼9 × 10–15 m2 s–1 at θ = 1.0 × 10–4 m3 m–3, where the film thickness = 0.9 nm. Given that the diffusion coefficients (D o) of Rb+ and Br– in bulk water (30 °C) are both ∼2.4 × 10–9 m2 s–1, we found the impedance factor f = D e/(θD o) is equal to 0.03 ± 0.02 at this very low saturation, in agreement with the predicted influence of interface tortuosity (τa) for diffusion along grain surfaces. Thus, reduced cross-sectional area (θ) and tortuosity largely accounted for the more than 5 orders of magnitude decrease in D e relative to D o as desaturation progressed down to nanoscale films.
ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.6b05891