Abstract
Alkalinity generation and metals retention were evaluated during the initial year of operation of a treatment wetland, consisting of four 185 m2 inseries cells comprised of alternating vertical-flow anaerobic substrate wetlands (VFs) and surface-flow aerobic settling ponds (SFs). The substrate in the VFs consists of spent mushroom substrate (SMS) and limestone gravel, supplemented with hydrated fly ash in a 20∶10∶1 ratio by volume. Approximately 15±4 L/min of acid mine drainage (AMD) from an abandoned underground coal mine in southeastern Oklahoma, USA, was directed to the system in October 1998 (mean influent water quality: 660 mg L−1 net acidity as CaCO3 eq., pH 3.4, 215 mg L−1 total Fe, 36 mg L−1 Al, 14 mg L−1 Mn, and 1000 mg L−1 SO4 −2). Flow through the first VF resulted in substantial increases in alkalinity, decreased metal concentrations and circumneutral pH. 258±84 mg L−1 of alkalinity was produced in the first VF by a combination of processes. Final discharge waters were net alkaline on all sampling dates (mean net alkalinity=136 mg L−1). Total Fe and Al concentrations decreased significantly from 216±45 to 44±28 mg L−1 and 36±6.9 to 1.29±4.4 mg L−1, respectively. Manganese concentrations did not change significantly in the first two cells, but decreased significantly in the second two cells. Mean acidity removal rates in the first VF (51 g m−2 day−1) were similar to those previously reported.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
APHA (1995) Standard methods for the examination of water and wastewater. 19th Edition, American Public Health Association. Washington, DC.
Canty GA, Everett JW (1998) An injection technique for in situ remediation of abandoned underground coal mines. Proc of the 15th Annual American Society for Surface Mining and Reclamation Meeting, St. Louis, MO. May 17–21, 1998.
Crisp T, Nairn RW, Strevett KA, Everett JW, Chen B (1998) Passive treatment using coal combustion products: results of a column study. Abstracts, 15th Annual National Meeting of American Society for Surface Mining and Reclamation, St. Louis, MO.
Hedin RS, Nairn RW, Kleinmann RLP (1994) Passive treatment of coal mine drainage. U.S. Bureau of Mines I.C. 9389. 37 pp.
Jage CR, Zipper CE, Hendricks, AC (2000) Factors effecting performance of successive alkalinity producing systems. In: W.L. Daniels and S.G. Richardson (eds.), Proc, 2000 Annual Meeting of the American Society for Surface Mining and Reclamation, Tampa, FL, pp. 451–458.
Kepler DA, McCleary EC (1994) Successive alkalinity producing systems (SAPS) for the treatment of acidic mine drainage. U.S. Bureau of Mines SP 06A-94, Volume 1. pp. 195–204.
Mercer MN (2000) Evaluating the performance of acid mine drainage treatment wetlands supplemented with coal combustion products and alternative organic substrates. Masters thesis, University of Oklahoma, Norman, OK 185 pp.
Nairn RW, Hedin RS (1992) Designing wetlands for the treatment of polluted coal mine drainage. In: M. C. Landin (ed.). Wetlands, Society of Wetland Scientists, Utica, MS, pp. 224–229.
Watzlaf GR, Pappas, DM (1996) Passive treatment of acid mine drainage in systems containing compost and limestone: Laboratory and field results. Proc, 13th Annual National Meeting of American Society for Surface Mining and Reclamation, Knoxville, TN.
Watzlaf GR, Schroeder KT, Kairies, C (2000) Long-term performance of alkalinity-producing passive systems for the treatment of mine drainage. In: W.L. Daniels and S.G. Richardson (eds.), A New Era of Land Reclamation, Proc, 2000 Annual Meeting of the American Society for Surface Mining and Reclamation, Tampa, FL, pp. 262–274.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Nairn, R.W., Mercer, M.N. Alkalinity generation and metals retention in a successive alkalinity producing system. Mine Water and the Environment 19, 124–133 (2000). https://doi.org/10.1007/BF02687260
Issue Date:
DOI: https://doi.org/10.1007/BF02687260