Improved Passive Treatment of Acid Mine Drainage in Mushroom Compost Amended with Crab-Shell Chitin
Publication: Journal of Environmental Engineering
Volume 136, Issue 6
Abstract
Crab-shell chitin, which is inherently high in calcium carbonate and nutrients, was tested as a multifunctional, fractional amendment to improve the effectiveness of spent mushroom compost (SMC), which is a low-cost, frequently used, but often underperforming substrate for treating acid mine drainage (AMD). Batch and continuous-flow column tests were used to evaluate different crab-shell/SMC mixtures for their ability to neutralize acidity, reduce sulfate, and remove metals in field-collected AMD. Alkalinity generation and the removal of manganese and sulfate were strongly correlated to the fraction of crab shell in the substrate: the treatment capacity increased from 36.7 L/kg for the traditional 90% SMC/10% limestone substrate up to 428 L/kg for 100% crab shell. The costs associated with adding crab shell to SMC were found to be minimal relative to the resulting improvement in water quality. Based on these data, it appears that a small fraction of crab shell (5–15%) does not provide a significant benefit over traditional compost and limestone substrates, but that larger fractions (50–100%) are much more efficient than traditional SMC substrates, especially for the removal of metals.
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Acknowledgments
This material is based on worked supported in part by the National Science Foundation CAREER Award No. NSFCBET-0644983. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect the views of the National Science Foundation. The support of the Department of Civil and Environmental Engineering and the College of Engineering at The Pennsylvania State University is also gratefully acknowledged.
References
American Public Health Association, American Water Works Association, and Water Environment Federation (APHA, AWWA, and WEF). (1998). Standard methods for the examination of water and wastewater, 20th Ed., L. S. Clesceri, A. E. Greenberg, and A. D. Eaton, eds., APHA, Baltimore.
Bamforth, S. M., Manning, D. A. C., Singleton, I., Younger, P. L., and Johnson, K. L. (2006). “Manganese removal from mine waters—Investigating the occurrence and importance of manganese carbonates.” Appl. Geochem., 21, 1274–1287.
Benner, S. G., Blowes, D. W., Gould, W. D., Herbert, R. B., and Ptacek, C. J. (1999). “Geochemistry of a permeable reactive barrier for metals and acid mine drainage.” Environ. Sci. Technol., 33(16), 2793–2799.
Brennan, R. A., Sanford, R. A., and Werth, C. J. (2006). “Biodegradation of tetrachloroethene by chitin fermentation products in a continuous flow column system.” J. Environ. Eng., 132(6), 664–673.
Christensen, B., Laake, M., and Lien, T. (1996). “Treatment of acid mine water by sulfate-reducing bacteria: Results from a bench scale experiment.” Water Res., 30(7), 1617–1624.
Daubert, L. N., and Brennan, R. A. (2007). “Passive remediation of acid mine drainage using crab shell chitin.” Environ. Eng. Sci., 24(10), 1475–1480.
Dvorak, D. H., Hedin, R. S., Edenborn, H. M., and McIntire, P. E. (1992). “Treatment of metal-contaminated water using bacterial sulfate reduction—Results from pilot-scale reactors.” Biotechnol. Bioeng., 40(5), 609–616.
Felse, P. A., and Panda, T. (1999). “Studies on applications of chitin and its derivatives.” Bioprocess Eng., 20(6), 505–512.
Hallberg, K. B., and Johnson, D. B. (2005). “Biological manganese removal from acid mine drainage in constructed wetlands and prototype bioreactors.” Sci. Total Environ., 338(1–2), 115–124.
Harkness, M., Farnum, R., Weesner, B., Foti, D., Wilke, W., and Smith, D. (2003). “The case for chitin.” Proc., 7th Int. Conf. on In Situ and On-Site Bioremediation, Batelle, Columbus, Ohio.
Johnson, D. B., and Hallberg, K. B. (2005). “Acid mine drainage remediation options: A review.” Sci. Total Environ., 338(1–2), 3–14.
Micera, G., Gessa, C., Melis, P., Premoli, A., Dallocchio, R., and Deiana, S. (1986). “Zinc(II) adsorption on aluminum hydroxide.” Colloids Surf., 17(4), 389–394.
Neculita, C. M., Zagury, G. J., and Bussiere, B. (2007). “Passive treatment of acid mine drainage in bioreactors using sulfate-reducing bacteria: Critical review and research needs.” J. Environ. Qual., 36(1), 1–16.
Ntougias, S., Zervakis, G. I., Kavroulakis, N., Ehaliotis, C., and Papadopoulou, K. K. (2004). “Bacterial diversity in spent mushroom compost assessed by amplified rDNA restriction analysis and sequencing of cultivated isolates.” Syst. Appl. Microbiol., 27(6), 746–754.
Pokrovsky, O. S., Viers, J., and Freydier, R. (2005). “Zinc stable isotope fractionation during its adsorption on oxides and hydroxides.” J. Colloid Interface Sci., 291(1), 192–200.
Pruden, A., Messner, N., Pereyra, L., Hanson, R. E., Hiibel, S. R., and Reardon, K. F. (2007). “The effect of inoculum on the performance of sulfate-reducing columns treating heavy metal contaminated water.” Water Res., 41(4), 904–914.
Robinson-Lora, M. A., and Brennan, R. A. (2009a). “Efficient metal removal and neutralization of acid mine drainage by crab-shell chitin and continuous-flow conditions.” Bioresour. Technol., 100(21), 5063–5071.
Robinson-Lora, M. A., and Brennan, R. A. (2009b). “The use of crab-shell chitin for biological denitrification: Batch and column tests.” Bioresour. Technol., 100(2), 534–541.
Rose, S., and Elliott, W. C. (2000). “The effects of pH regulation upon the release of sulfate from ferric precipitates formed in acid mine drainage.” Appl. Geochem., 15(1), 27–34.
Sikora, F. J., Behrends, L. L., Brodie, G. A., and Taylor, H. N. (2000). “Design criteria and required chemistry for removing manganese in acid mine drainage using subsurface flow wetlands.” Water Environ. Res., 72(5), 536–544.
Stark, L. R., Wenerick, W. R., Williams, F. M., Stevens, S. E., and Wuest, P. J. (1994). “Restoring the capacity of spent mushroom compost to treat coal-mine drainage by reducing the inflow rate—A microcosm experiment.” Water Air Soil Pollut., 75(3–4), 405–420.
Steed, V. S., Suidan, M. T., Gupta, M., Miyahara, T., Acheson, C. M., and Sayles, G. D. (2000). “Development of a sulfate-reducing biological process to remove heavy metals from acid mine drainage.” Water Environ. Res., 72(5), 530–535.
Stewart, D. P. C., Cameron, K. C., and Cornforth, I. S. (1998). “Inorganic-N release from spent mushroom compost under laboratory and field conditions.” Soil Biol. Biochem., 30(13), 1689–1699.
U.S. EPA. (1999). “Acid mine drainage prediction.” Rep. No. EPA530-R-94-036, U.S. EPA, Washington, D.C.
Venot, C., Figueroa, L., Brennan, R. A., Wildeman, T. L., Reisman, D., and Sieczkowski, M. (2008). “Comparing chitin and organic substrates on the national tunnel waters in Blackhawk, Colorado: Unusual manganese removal.” Proc., National Meeting of the American Society of Mining and Reclamation: New Opportunities to Apply Our Science, American Society of Mining and Reclamation, Richmond, Va.
Vera, S. M., Werth, C. J., and Sanford, R. A. (2001). “Evaluation of different polymeric organic materials for creating conditions that favor reductive processes in groundwater.” Biorem. J., 5(3), 169–181.
Vile, M. A., and Wieder, R. K. (1993). “Alkalinity generation by Fe(III) reduction versus sulfate reduction in wetlands constructed for acid mine drainage treatment.” Water Air Soil Pollut., 69(3–4), 425–441.
Watzlaf, G. R., and Hyman, D. M. (1995). “Limitations of passive systems for the treatment of mine drainage.” Proc., 17th Annual Conf. of the National Association of Abandoned Mine Land Programs, NAAMLP, French Lick, Ind., 186–199.
Waybrant, K. R., Ptacek, C. J., and Blowes, D. W. (2002). “Treatment of mine drainage using permeable reactive barriers: Column experiments.” Environ. Sci. Technol., 36(6), 1349–1356.
Willow, M. A., and Cohen, R. R. H. (2003). “pH, dissolved oxygen, and adsorption effects on metal removal in anaerobic bioreactors.” J. Environ. Qual., 32(4), 1212–1221.
Zagury, G. J., Kulnieks, V. I., and Neculita, C. M. (2006). “Characterization and reactivity assessment of organic substrates for sulphate-reducing bacteria in acid mine drainage treatment.” Chemosphere, 64(6), 944–954.
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© 2010 ASCE.
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Received: Jun 22, 2009
Accepted: Nov 12, 2009
Published online: Nov 14, 2009
Published in print: Jun 2010
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