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TECHNICAL REPORTS

Waste Management

Multiple-Year Water Balance of Soil Covers in a Semiarid Setting

Pacific Northwest National Laboratory, Richland, WA 99354

^* Corresponding author (mike.fayer{at}pnl.gov)

Received for publication October 20, 2004. Surface covers are used to isolate contaminants in hazardous and low-level radioactive sites for time frames ranging from hundreds of years to millennia or more. In the absence of data for such durations, the long-term performance of surface barriers can only be represented with short-term tests or inferred from analogs and modeling. This paper provides evidence of field performance of soil covers for periods up to 17 yr. The results of lysimeter studies from a semiarid site in Washington State show that a cover design known as the Hanford Barrier, which consists of 1.5 m of silt loam above a sand–gravel capillary break, can nearly eliminate drainage. The results were similar if plants were present or not, demonstrating the robustness of the design. Furthermore, reducing the silt loam thickness to 1.0 m (as might occur via erosion), with or without plants, did not lead to drainage. When irrigated to mimic 3x average precipitation conditions, the vegetated Hanford Barrier continued to prevent drainage. Overall, the results showed no loss in performance during the 17 yr of testing. Only when plants were eliminated completely from the 3x precipitation test did drainage occur (rates ranged from 6 to 16 mm yr^–1). In a separate test, replacing the top 0.2 m of silt loam with dune sand and reducing the plant cover did not lead immediately to the onset of drainage, but soil matric heads within the silt loam noticeably increased. This observation suggests that dune sand migration onto a surface cover has the potential to reduce a cover's ability to minimize deep drainage.

Abbreviations: AP, ambient precipitation • DRV, deep-rooted vegetation • EP, enhanced precipitation • FLTF, Field Lysimeter Test Facility • HB, Hanford Barrier • HMS, Hanford Meteorological Station • NV, novegetation • SRV, shallow-rooted vegetation

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