H13P-08
Silver Nanoparticle Transport Through Soil: Illuminating the Pore-Scale Processes 

Monday, 14 December 2015: 15:25
3016 (Moscone West)
Ian L Molnar1, Clinton S Willson2, Jason Gerhard3 and Denis M O'Carroll1, (1)University of Western Ontario, London, ON, Canada, (2)Louisiana State University, Civil and Environmental Engineering, Baton Rouge, LA, United States, (3)University of Western Ontario, Department of Civil and Environmental Engineering, London, ON, Canada
Abstract:
For nanoparticle transport through soil, the pore-scale (i.e., tens to hundreds of grains and pores) is a crucial intermediate scale which links nanoparticle-surface interactions with field-scale transport behaviour. However, very little information exists on how nanoparticles behave within real three-dimensional pore spaces. As a result, pore-scale processes are poorly characterized for nanoparticle systems and, subsequently, continuum-scale transport models struggle to describe commonly observed ‘anomalous’ behaviour such as extended tailing.

This knowledge gap is due to two primary factors: an inability to experimentally observe nanoparticles within real pore spaces, and the computationally expensive models required to simulate nanoparticle movement. However, due to recent advances in Synchrotron X-Ray Computed Microtomography (SXCMT), it is now possible to quantify in-situ pore-scale nanoparticle concentrations during transport through real 3-dimensional porous media [1]. Employing this SXCMT quantification method to examine real nanoparticle/soil transport experiments has yielded new insights into the pore-scale processes governing nanoparticle transport. By coupling SXCMT nanoparticle quantification method with Computational Fluid Dynamics (CFD) simulations we are able to construct a better picture of how nanoparticles flow through real pore spaces.

This talk presents SXCMT/CFD analyses of three silver nanoparticle transport experiments. Silver nanoparticles were flushed through three different sands to characterize the influence of grain distribution and retention rates on pore-scale flow and transport processes. These CFD/SXCMT analyses illuminate how processes such as temporary hydraulic retention govern nanoparticle transport. In addition, the observed distributions of pore water velocities and nanoparticle mass flow rates challenge the standard conceptual model of nanoparticle transport, suggesting that pore-scale processes require explicit consideration in order to fully describe nanoparticle ransport. References

 1. Molnar, I.L., et al., Method for Obtaining Silver Nanoparticle Concentrations within a Porous Medium via Synchrotron X-ray Computed Microtomography. Environmental Science & Technology, 2014. 48(2): p. 1114-1122.

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