Pore-scale visualization of colloid transport and retention in partly saturated porous media

In unsaturated porous media, sorption of colloids at the air-water (AW) interface is accepted as a mechanism for controlling colloid retention and mobilization. However, limited actual pore-scale observations of colloid attachment to the AW interface have been made. To further investigate these proc...

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Veröffentlicht in:	Vadose zone journal 2004-05, Vol.3 (2), p.444-450
Hauptverfasser:	Crist, J.T, McCarthy, J.F, Zevi, Y, Baveye, P, Throop, J.A, Steenhuis, T.S
Format:	Artikel
Sprache:	eng
Schlagworte:	air-water interface colloidal materials experimental studies infiltration (hydrology) mass transfer mobilization partitioning physical models pollutants porosity porous materials porous media retention sand sandy soils soil colloids soil pollution soil transport processes soils sorption transport unsaturated conditions unsaturated flow unsaturated zone vadose zone visualization
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creator	Crist, J.T McCarthy, J.F Zevi, Y Baveye, P Throop, J.A Steenhuis, T.S
description	In unsaturated porous media, sorption of colloids at the air-water (AW) interface is accepted as a mechanism for controlling colloid retention and mobilization. However, limited actual pore-scale observations of colloid attachment to the AW interface have been made. To further investigate these processes, a real-time pore-scale visualization method was developed. The method builds on the light transmission technique for fingered flow studies in packed-sand infiltration chambers and combines it with high-resolution, electro-optical hardware and public domain imaging software. Infiltration and drainage of suspensions of hydrophilic negatively charged carboxylated latex microspheres provides compelling visual evidence that colloid retention in sandy porous media occurs via trapping in the thin film of water where the AW interface and the solid interface meet, the air-water-solid (AWS) interface. With this modified theory of trapped colloids at the AWS interface, we are able to explain the apparent discrepancy between previous experimental evidence of hydrophilic colloids seemingly partitioning to the AW interface and more recent findings that suggest this type of colloid does not adsorb at the AW interface.
doi_str_mv	10.2113/3.2.444
format	Article
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However, limited actual pore-scale observations of colloid attachment to the AW interface have been made. To further investigate these processes, a real-time pore-scale visualization method was developed. The method builds on the light transmission technique for fingered flow studies in packed-sand infiltration chambers and combines it with high-resolution, electro-optical hardware and public domain imaging software. Infiltration and drainage of suspensions of hydrophilic negatively charged carboxylated latex microspheres provides compelling visual evidence that colloid retention in sandy porous media occurs via trapping in the thin film of water where the AW interface and the solid interface meet, the air-water-solid (AWS) interface. With this modified theory of trapped colloids at the AWS interface, we are able to explain the apparent discrepancy between previous experimental evidence of hydrophilic colloids seemingly partitioning to the AW interface and more recent findings that suggest this type of colloid does not adsorb at the AW interface.</abstract><pub>Soil Science Society of America</pub><doi>10.2113/3.2.444</doi><tpages>7</tpages><oa>free_for_read</oa></addata></record>
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subjects	air-water interface colloidal materials experimental studies infiltration (hydrology) mass transfer mobilization partitioning physical models pollutants porosity porous materials porous media retention sand sandy soils soil colloids soil pollution soil transport processes soils sorption transport unsaturated conditions unsaturated flow unsaturated zone vadose zone visualization
title	Pore-scale visualization of colloid transport and retention in partly saturated porous media
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