Abstract
The carbonate aquifers of central Tennessee and Kentucky are vulnerable to dissolved and non-aqueous phase contamination due to contaminant transport through sinkholes, fractures, and other karst features. The complexity of local karst hydrology often prevents the efficient removal of contaminants through the use of traditional pump-and-treat methods. Bioremediation, in some instances, is a viable remediation option, with suitable hydrological, geochemical, and microbial site conditions. Tracer studies are essential for characterizing site hydrology and estimating residence times. Sample collection and evaluation of the geochemical conditions and existing bacterial types are critical as part of the site evaluation. Supplements have been used to stimulate specific microbial populations and foster geochemical conditions which enhance or stimulate degradation or immobilization of the contaminants in a karst aquifer. Bacteria indigenous to Tennessee and Kentucky karst systems are well adapted to a variety of metabolic capabilities and aquifer conditions. Non-traditional groundwater models that incorporate residence time distribution and decay rates are useful tools in the remediation decision-making process.
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Barton, H.A., and D.E. Northup. 2007. Geomicrobiology in cave environments: Past, current and future perspectives. Journal of Cave and Karst Studies 69 (1): 163–178.
Brown, J.T., Z. Ahmed, and T.D. Byl. 2014. Non-target bacterial response to white-nose syndrome treatment: Quaternary ammonia compounds and linear alkylbenzene sulfonate. In U.S. geological survey karst interest group proceedings, ed. E.L. Kuniansky, and L.E. Spangler, 155 p. Apr 29–May 2, U.S. Geological Survey S.I.R. 2014-5035, Carlsbad, NewMexico. 10.3133/sir20145035.
Byl, T.D., and S.D. Williams. 2000. Biodegradation of chlorinated ethenes at a karst site in Middle Tennessee. U.S. Geological Survey Water-Resources Investigations Report 99–4285, 58 p.
Byl, T.D., G.E. Hileman, S.D. Williams, and J.J. Farmer. 2001. Geochemical and microbial evidence of fuel biodegradation in a contaminated karst aquifer in southern Kentucky. In U.S. geological survey karst interest group proceedings, ed. E.L. Kuniansky, 151–156. Feb 13–16, U.S. Geological Survey Water-Resources Investigations Report 01-4011, St. Petersburg, Florida.
Byl, T.D., D.W. Metge, D.T. Agymang, M. Bradley, G. Hileman, and R.W. Harvey. 2014. Adaptations of indigenous bacteria to fuel contamination in karst aquifers in south-central Kentucky. Journal of Cave and Karst Studies 76 (2): 104–113.
Chakraborti, K., G. Hileman, L. Hampton, M. Greene, and T.D. Byl. 2003. Enhanced biodegradation of TCE in a karst aquifer using lactic acid, molasses and soy milk. In Proceedings from the 14th tennessee water resources symposium, Apr 9–11, Montgomery Bell State Park, Burns, Tennessee.
Field, M.S. 1993. Karst hydrology and chemical contamination. Journal of Environmental Systems 22 (1): 1–26.
King, L.K., R.D. Painter, and T.D. Byl. 2005. Adaptation of the Residence Time Distribution (RTD)-biodegradation model to quantify peroxide-enhanced biodegradation in a single karst well. In U.S. geological survey karst interest group proceedings, ed. E.L. Kuniansky, 174–179. Sept 12–15, U.S. Geological Survey Scientific Investigations Report 2005-5160, Rapid City, South Dakota.
Kölbel-Boelke, J., E.-M. Anders, and A. Nehrkorn. 1988. Microbial communities in the saturated groundwater environment, II. Diversity of bacterial communities in a Pleistocene sand aquifer and their in vitro activities. Microbial Ecology 16: 31–48. doi:10.1007/BF02097403.
Kuniansky, E. 2014. Taking the mystery out of mathematical model applications to karst aquifers—A primer. In U.S. geological survey karst interest group proceedings, ed. E.L. Kuniansky, and L.E. Spangler, 155 p. Apr 29–May 2, U.S. Geological Survey Scientific Investigations Report 2014-5035, Carlsbad, New Mexico. 10.3133/sir20145035.
Northup, D.E., and K.H. Lavoie. 2001. Geomicrobiology of caves: A review. Geomicrobiology Journal 18: 199–222. doi:10.1080/01490450152467750.
Painter, R.D., S. Kochary, and T.D. Byl. 2005. Free-living bacteria or attached bacteria: Which contributes more to bioremediation? In U.S. geological survey karst interest group proceedings, ed. E.L. Kuniansky, 180–186. Sept 12–15, U.S. Geological Survey Scientific Investigations Report 2005-5160, Rapid City, South Dakota.
Spear, L., A. Williams, J. Brooks, C. Cobb, B. Cobb, M. Martin, P. Armstrong, M. Bradley, and T. Byl. 2011. Aromatic-ring biodegradation in soils from a crude oil spill on Clear Creek, Obed Wild and Scenic River National Park. In Proceedings from the 21st tennessee water resources symposium, 29. Apr 13–15, Montgomery Bell State Park, Burns, Tennessee. http://tnawra.er.usgs.gov/2011/Proceedings11.pdf.
Weary, D.J., and D.H. Doctor. 2014. Karst in the United States: A digital map compilation and database. U.S. Geological Survey Open-File Report 2014–1156, 23 p. 10.3133/ofr20141156.
Wolfe, W.J., C.J. Haugh, A. Webbers, and T.H. Diehl. 1997. Preliminary conceptual models of the occurrence, fate, and transport of chlorinated solvents in karst aquifers of Tennessee. U.S. Geological Survey Water-Resources Investigations Report 97-4097, 80 p.
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Byl, T., Bradley, M., Thomas, L.K., Painter, R. (2018). Bioremediation Potential in Karst Aquifers of Tennessee and Kentucky. In: White, W., Herman, J., Herman, E., Rutigliano, M. (eds) Karst Groundwater Contamination and Public Health. Advances in Karst Science. Springer, Cham. https://doi.org/10.1007/978-3-319-51070-5_10
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