Comparison of three labeled silica nanoparticles used as tracers in transport experiments in porous media. Part II: Transport experiments and modeling

Three types of labeled silica nanoparticles were used in transport experiments in saturated sand. The goal of this study was to evaluate both the efficiency of labeling techniques (fluorescence (FITC), metal (Ag(0) core) and radioactivity (110mAg(0) core)) in realistic transport conditions and the r...

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Veröffentlicht in:Environmental pollution (1987) 2014-01, Vol.184, p.613-619
Hauptverfasser: Vitorge, Elsa, Szenknect, Stéphanie, Martins, Jean M.-F., Barthès, Véronique, Gaudet, Jean-Paul
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Sprache:eng
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Zusammenfassung:Three types of labeled silica nanoparticles were used in transport experiments in saturated sand. The goal of this study was to evaluate both the efficiency of labeling techniques (fluorescence (FITC), metal (Ag(0) core) and radioactivity (110mAg(0) core)) in realistic transport conditions and the reactive transport of silica nanocolloids of variable size and concentration in porous media. Experimental results obtained under contrasted experimental conditions revealed that deposition in sand is controlled by nanoparticles size and ionic strength of the solution. A mathematical model is proposed to quantitatively describe colloid transport. Fluorescent labeling is widely used to study fate of colloids in soils but was the less sensitive one. Ag(0) labeling with ICP-MS detection was found to be very sensitive to measure deposition profiles. Radiolabeled (110mAg(0)) nanoparticles permitted in situ detection. Results obtained with radiolabeled nanoparticles are wholly original and might be used for improving the modeling of deposition and release dynamics. •Three kinds of labeled nanotracers were used in transport experiments in sand columns.•They were used as surrogates of silica nanoparticles or mineral colloid.•Deposition depending on colloid size and ionic strength was observed and modeled.•Fluorescence labeling had the worse detection limit but was the more convenient.•Radiolabeled nanotracers were detected in situ in a non destructive way. Follow the kinetics of transport, deposition and release of silica nanoparticles with suitably labeled nanoparticles.
ISSN:0269-7491
1873-6424
DOI:10.1016/j.envpol.2013.08.016