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Physical Sciences Division
Research Highlights

October 2010

Trapped Toxins

Architecture of soil particles greatly influences if, when pollutants migrate

Abstract of pore connectivity
Scientists found that the connections between pores in sand and other medium influence the speed with which pollutants migrate. The fewer connections between the pores, the greater the probability that contaminant molecules will take a very long time to leave the grain. Enlarge Image

Results: Pollutants can find themselves ensnared underground with few options for escape, according to a study by scientists at Iowa State University, University of Texas at Arlington, and Pacific Northwest National Laboratory. The team found that, while many factors influence contaminant migration, one of the most important are the architecture of the soil grains. The less pore connectivity, the greater the probability that contaminants will take a long time to leave the grain.

Why it matters: Understanding if and when a pollutant moves from an industrial to an agricultural site allows scientists to better predict pollutant migration, test remediation systems, and determine the effectiveness of cleanup projects. While the study was done on uranium, a concern at former nuclear weapons production sites, the research applies to chemicals more commonly associated with machine shops and dry cleaners.

Methods: Existing models that predict the rates of desorption and diffusion from the subsurface did not account for real-world grain-scale properties. So, the scientists focused on the desorption, diffusion, and migration of uranium from inside the individual subsurface particles. They conducted numerical calculations and evaluations of diffusion and mass transfer in complex granular porous media, using resources at EMSL.

The results were surprising. The fundamental process of desorption and diffusion from the granular medium to the surrounding liquid phase was much slower than projected by previous models. Also, the team found the rate of desorption dramatically decreased over time. This phenomenon is governed by connectivity, the interconnected architecture of microscopic pores inside individual grains.

What's next? Laboratory and field research is under way to characterize grain-scale pore architecture and to investigate the larger-scale manifestation of the grain-scale contaminant diffusion.

Acknowledgments: This work was funded by the U.S. Department of Energy's Office of Biological and Environmental Research.

Computational capabilities at DOE's EMSL, a national scientific user facility, were vital to this study.

The work was done by Robert Ewing of Iowa State University, Qinhong Hu of the University of Texas at Arlington, and Chongxuan Liu of Pacific Northwest National Laboratory.

Reference: Ewing RP, Q Hu, and C Liu. 2010. "Scale Dependence of Intragranular Porosity, Tortuosity, and Diffusivity." Water Resources Research 46, W06513. DOI:10.1029/
2009WR008183.


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