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Remediation of NAPL Source Zones: Lessons Learned from Field Studies at Hill and Dover AFB
Author(s) -
McCray John E.,
Tick Geoffrey R.,
Jawitz James W.,
Gierke John S.,
Brusseau Mark L.,
Falta Ronald W.,
Knox Robert C.,
Sabatini David A.,
Annable Michael D.,
Harwell Jeffrey H.,
Wood A. Lynn
Publication year - 2011
Publication title -
groundwater
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.84
H-Index - 94
eISSN - 1745-6584
pISSN - 0017-467X
DOI - 10.1111/j.1745-6584.2010.00783.x
Subject(s) - environmental remediation , groundwater , environmental science , groundwater remediation , waste management , contamination , tracer , flushing , remedial action , environmental engineering , geology , engineering , geotechnical engineering , medicine , ecology , physics , endocrinology , nuclear physics , biology
Innovative remediation studies were conducted between 1994 and 2004 at sites contaminated by nonaqueous phase liquids (NAPLs) at Hill and Dover AFB, and included technologies that mobilize, solubilize, and volatilize NAPL: air sparging (AS), surfactant flushing, cosolvent flooding, and flushing with a complexing‐sugar solution. The experiments proved that aggressive remedial efforts tailored to the contaminant can remove more than 90% of the NAPL‐phase contaminant mass. Site‐characterization methods were tested as part of these field efforts, including partitioning tracer tests, biotracer tests, and mass‐flux measurements. A significant reduction in the groundwater contaminant mass flux was achieved despite incomplete removal of the source. The effectiveness of soil, groundwater, and tracer based characterization methods may be site and technology specific. Employing multiple methods can improve characterization. The studies elucidated the importance of small‐scale heterogeneities on remediation effectiveness, and fomented research on enhanced‐delivery methods. Most contaminant removal occurs in hydraulically accessible zones, and complete removal is limited by contaminant mass stored in inaccessible zones. These studies illustrated the importance of understanding the fluid dynamics and interfacial behavior of injected fluids on remediation design and implementation. The importance of understanding the dynamics of NAPL‐mixture dissolution and removal was highlighted. The results from these studies helped researchers better understand what processes and scales are most important to include in mathematical models used for design and data analysis. Finally, the work at these sites emphasized the importance and feasibility of recycling and reusing chemical agents, and enabled the implementation and success of follow‐on full‐scale efforts.

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