05/23/13 Portland, Ore.
The “next big thing” for cleanup of contaminated soil and groundwater is to use nano-sized iron metal to degrade the pollutants. This technology passed from laboratory research to field-scale deployment in less than a decade.
The technology emerged so quickly that there are still outstanding questions regarding its performance in the field. A detailed pilot-scale study to address these questions was recently reported by researchers at the Oregon Health & Science University (OHSU).
The study, published in the February 2013 edition of Environmental Science & Technology, examined the fate of nano zerovalent iron (nZVI) during injection into a large three-dimensional model aquifer. The model aquifer is 10 x 10 meters in area, 2.4-meter deep, and filled with six layers of sand and clay. The facility for this was started 20 years ago by Professor Richard Johnson, and was one of only a few in the world with capacity for such large experiments.
“Previous large scale studies of nZVI injection have not included sufficient characterization to really know how effective the processes was,” said Johnson, the lead investigator on the project and professor in OHSU’s Institute of Environmental Health. “We believe that the combination of monitoring methods, and modeling, that we used provides the first definitive evidence regarding what can actually be achieved in the field.”
Johnson led a team of eight OHSU researchers to monitor and track the nZVI injected into the aquifer. Each research member was responsible for one or more characterization methods. The resulting data, combined with numerical modeling of the results, provided the most detailed characterization to date of nZVI injection into the subsurface.
One important finding from the study is that simply monitoring the color in groundwater sampling wells can provide valuable information about the transport and fate of nZVI. Color changes not only are a sensitive indicator of nZVI breakthrough, but they also show when the nZVI has been oxidized by the aquifer. The resulting yellow color reflects the “reductant demand” of the aquifer.
In addition to the nZVI, the injected fluid contained several species that served as conservative tracers of fluid movement in the aquifer. These data, together with mathematical modeling of the results, showed that formation of bubbles of hydrogen gas (from reactions of the nZVI) influenced the flow of groundwater.
“This study clarifies both the pros and cons of this technology,” said Paul Tratnyek, co-author and professor with at OHSU’s Institute of Environmental Health and co-Principal Investigator on the project. “Through this work, we hope to help ensure that when the technology gets used, it gets used correctly, so the environmental cleanup goals are reached with a minimum of surprises or failures.”
This study was funded by the Strategic Environmental Research and Development Program (SERDP) as a supplement to ER-1485 (Fundamental Study of the Delivery of Nanorion to DNAPL Source Zones in Naturally Heterogenous Field Systems), which was led by colleagues at Carnegie Mellon University. The full report form this project, including results from the pilot test, is available here.
ABOUT OHSU INSTITUTE OF ENVIRONMENTAL HEALTH
OHSU Institute of Environmental Health believes preventative medicine starts with a healthy environment. There is overwhelming evidence that human activities and the global climate are affecting environmental health and sustainability. Increasingly, these consequences are causing serious implications for human health. IEH seeks to develop scientific understanding in environmental and biomolecular systems that elucidates environmental processes and their links to human health.