Abstract
We report on the concentration of heavy metals (cadmium, chromium, cobalt, copper, iron, and lead) in the water and sediment of Lake Greenwood and the streams and creeks that flow into the lake. Our results show heavy metal concentrations well below levels that were reported in 2012. The heavy metal concentrations reported for Lake Greenwood were on the order of the established background levels; our measurements indicate that heavy metal concentrations are now well below the established background levels. The concentration of heavy metals in creeks sediment and lake sediment was not statistically different for most metals (copper was statistically different). This significant drop in concentration suggests that the major flooding which occurred in 2015 has drastically altered the heavy metal profile of Lake Greenwood and the creeks which flow into the lake. The effect of introducing large volumes of relatively unweathered sediment has an observed lowering of the concentration of heavy metals. For all metals at all sites, the measured concentration of heavy metals in water samples collected was below the screening level established by the US Environmental Protection Agency. Also, our results also call into question the continued use of previously established background concentration of heavy metals after a significant flooding event, as the addition of large volumes of fresh sediment from flooding events significantly changes the heavy metal concentration.
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References
Andersen, C. B., & Sargent, K. A. (2001). Fluvial geochemistry of selected tributary watersheds in the Enoree River Basin, Northwestern South Carolina. South Carolina Geology, 43, 57–71.
Audry, S., Schäfer, J., Blanc, G., Bossy, C., & Lavaux, G. (2004). Anthropogenic components of heavy metal (cd, Zn, cu, Pb) budgets in the lot-Garonne fluvial system (France). Applied Geochemistry, 19(5), 769–786.
Birch, G., Siaka, M., & Owens, C. (2001). The source of anthropogenic heavy metals in fluvial sediments of a rural catchment: Coxs River, Australia. Water, Air, and Soil Pollution, 126, 13–35.
Bubb, J. M., & Lester, J. N. (1996). Factors controlling the accumulation of metals within fluvial systems. Environmental Monitoring and Assessment, 41(1), 87–105.
Canova, J. L. (1999). Elements in South Carolina inferred background soil and stream sediment samples. South Carolina Geology, 41(1), 11–25.
Ciszewski, D., & Grygar, T. M. (2016). A review of flood-related storage and remobilization of heavy metal pollutants in river systems. Water, Air, and Soil Pollution, 227(7), 239.
Consortium, S.-R. W. (2005). State of the watershed report 2005. Greenville.
Dey, S., & Islam, A. (2015). A review on textile wastewater characterization in Bangladesh. Resources and Environment, 5(1), 15–44.
Franklin, R. E., Duis, L., Smith, B. R., Brown, R., & Toler, J. E. (2003). Elemental concentrations in soils of South Carolina. Soil Science, 168(4), 280–291.
Jaishankar, M., Tseten, T., Anbalagan, N., Mathew, B. B., & Beeregowda, K. N. (2014). Toxicity, mechanism and health effects of some heavy metals. Interdisciplinary Toxicology, 7(2), 60–72.
Koli, A. K., & McClary, E. (1978). Magnitude of mercury levels in fish muscle tissue from South Carolina waters. Bulletin of the Chemical Society of Japan, 51(5), 1521–1524.
Li, Z., Wang, C., Emrich, C. T., & Guo, D. (2017). A novel approach to leveraging social media for rapid flood mapping: A case study of the 2015 South Carolina floods. Cartography and Geographic Information Science, 45(2), 97–110.
Martin, S., & Griswold, W. (2009). Human health effects of heavy metals. Environmetnal Science and Technology Briefs for Citizens, 15, 1–6.
Mierzejewski, J., Haney, D. C., & van den Hurk, P. (2014). Biomarker responses in sunfish species and largemouth bass from the Saluda River, South Carolina. Ecotoxicology and Environmental Safety, 110, 8–15.
Norton, R. (2018). Textile mills still producing in palmetto state. GSA Business Report. https://gsabusiness.com/news/manufacturing/74436/. Accessed 20 November 2019.
Otter, R. R., Schreiber, E. A., van den Hurk, P., & Klaine, S. J. (2012). Assessment of heavy metal and PAH exposure in largemouth bass (Micropterus salmoides) in the Reedy River watershed, South Carolina, USA: A multi-season assessment of metallothionein and bile fluorescence. Environmental Toxicology and Chemistry, 31(12), 2763–2770.
Palanques, A., Grimalt, J., Belzunces, M., Estrads, F., Puig, P., & Guillen, J. (2014). Massive accumulation of highly polluted sedimentary deposits by river damming. Science of the Total Environment, 497–498, 369–381.
Sharma, R. K., & Agrawal, M. (2005). Biological effects of heavy metals: An overview. Journal of Environmental Biology, 26, 301–313.
Stern, B. R. (2010). Essentiality and toxicity in copper health risk assessment: Overview, update and regulatory considerations. Journal of Toxicology and Environmental Health Part A, 73(2–3), 114–127.
Stevenson, E. (2017). Textile industry is alive and well. Greenville Business Magazine. http://www.greenvillebusinessmag.com/2017/11/01/159008/textile-industry-is-alive-and-well. Accessed 20 November 2019.
Stoker, H. S., & Seager, S. L. (1976). Environmental chemistry: Air and water pollution (2nd ed.). Glenview: Scott, Foresman and Company.
Tchounwou, P. B., Yedjou, C. G., Patlolla, A. K., & Sutton, D. J. (2012). Heavy metal toxicity and the environment. In A. Luch (Ed.), Molecular, clinical, and environmental toxicology (Vol. 101, pp. 365–396). Basel: Springer.
US EPA. (1996). Method 3050B: Acid digestion of sediments, sludges, and soils. Wasington, DC: United States Environmental Protection Agency.
US EPA. (2019). Regional screening level (RSL) resident soil to GW table.
Wang, C., Li, Z., & Huang, X. (2018). Geospatial assessment of wetness dynamics in the October 2015 SC flood with remote sensing and social media. Southeastern Geographer, 58(2), 164–180.
Water, S. C. D. of H. and E. C. B. of. (1998). Watershed water quality assessment Saluda River basin. SC: Columbia.
Works, C. of P. (2019). 2019 annual drinking water quality report. Greenwood.
Acknowledgments
We thank the State of South Carolina and Lander University for providing the funds to purchase the graphite furnace atomic absorption spectrometer. The authors would like to thank Dr. Daniel Pardieck for many helpful discussions.
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Dukes, A.D., Eklund, R.T., Morgan, Z.D. et al. Heavy Metal Concentration in the Water and Sediment of the Lake Greenwood Watershed. Water Air Soil Pollut 231, 11 (2020). https://doi.org/10.1007/s11270-019-4364-x
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DOI: https://doi.org/10.1007/s11270-019-4364-x