Kathleen S. Smith U.S. Geological Survey, Denver, CO, [email protected] CLU-IN Webinar Series on Hardrock Mining Geochemistry and Hydrology Sampling, Monitoring, and Remediation at Mine Sites Workshop 3, March 5, 2013 References for Sampling Considerations at Mining Sites (yellow highlight indicates paper provided in CLU-IN Additional Resources) Al-Abed, S.R., Hageman, P.L., Jegadeesan, G., Madhavan, N., and Allen, D., 2006, Comparative evaluation of short-term leach tests for heavy metal release from mineral processing waste: Science of the Total Environment, v. 364, p. 14–23. Bencala, K.E., 2005, Hyporheic exchange flows, in M.G. Anderson (ed.), Encyclopedia of Hydrological Sciences, v. 3(10): New York, Wiley, p. 1-7. (Available online at http://water.usgs.gov/nrp/proj.bib/Publications/2005/bencala.2005.pdf) Braaten, R., and Gates, G., 2002, Groundwater-surface water interaction in NSW: a discussion paper. NSW DLWC (Sydney). Chapin, T.P., and Todd, A.S., 2012, MiniSipper: A new in situ water sampler for high-resolution, long-duration acid mine drainage monitoring. Science of the Total Environment, v. 439, p. 343-353. Diehl, S.F., Hageman, P.L., and Smith, K.S., 2006, What’s weathering? Mineralogy and field leach studies in mine waste, Leadville and Montezuma mining districts, Colorado, in Proceedings of the Seventh International Conference on Acid Rock Drainage (ICARD 7), St. Louis, Missouri, March 26-30, 2006, p. 507-527. (Available online at http://www.imwa.info/docs/imwa_2006/0507-Diehl-CO.pdf) Diehl, S.F., Hageman, P.L., Smith, K.S., Koenig, A.E., Fey, D.L., and Lowers, H.A., 2006, What’s weathering in mine waste? Mineralogic evidence for sources of metals in leachates, in Proceedings of the Hard Rock Mining 2006 Conference, Tucson, Arizona, November 14-16, 2006. Diehl, S.F., Hageman, P.L., and Smith, K.S., 2008, What is weathering in mine waste? Mineralogic evidence for sources of metals in leachates, Chapter A., in P.L. Verplanck (ed.), Understanding contaminants associated with mineral deposits: U.S. Geological Survey Circular 1328, p. 4-7. (Available online at http://pubs.usgs.gov/circ/1328/) Ficklin, W.H. and Mosier, E.L., 1999, Field methods for sampling and analysis of environmental samples for unstable and selected stable constituents, in Plumlee, G.S., and Logsdon, M.J., eds., The environmental geochemistry of mineral deposits, Part A: Processes, techniques, and health issues, Reviews in Economic Geology, vol. 6A: Littleton, Colorado, Society of Economic Geologists, Inc., p. 249–264. Gammons, C.H., and Nimick, D.A., 2010, Presentation at the SEG Environmental Geochemistry for Modern Mining Short Course, Denver, Colorado, October 29-30, 2010. Gammons, C.H., Nimick, D.A., Parker, S.R., Cleasby, T.E., and McCleskey, R.B., 2005, Diel behavior of iron and other trace metals in a mountain stream with acidic to neutral pH: Fisher Creek, Montana, USA: Geochim. Cosmochim. Acta, v. 69, p. 2505–2516. Gammons, C.H., Milodragovich, L., and Belanger-Woods, J., 2007, Influence of diurnal cycles on monitoring of metal concentrations and loads in streams draining abandoned mine lands: An example from High Ore Creek, Montana: Environ. Geol., v. 53, p. 611–622. Hageman, P.L., 2007, U.S. Geological Survey Field Leach Test for Assessing Water Reactivity and Leaching Potential of Mine Wastes, Soils, and Other Geologic and Environmental Materials: U.S. Geological Survey Techniques and Methods, book 5, chap. D3. Reston, VA. (Available online at http://pubs.usgs.gov/tm/2007/05D03/pdf/TM5-D3_508.pdf) Hageman, P.L., and Briggs, P.H., 2000, A simple field leach for rapid screening and qualitative characterization of mine waste material on abandoned mine lands, in Proceedings, 5th International Conference on Acid Rock Drainage (ICARD 2000). Littleton, CO: Society for Mining, Metallurgy, and Exploration. p. 1463–1475. (Available online at http://crustal.usgs.gov/projects/minewaste/pdfs/hageman1.pdf) Hammarstrom, J.M., and Smith, K.S., 2002, Geochemical and mineralogic characterization of solids and their effects on waters in metal-mining environments, Ch. B, in Seal, R.R., II, and Foley, N.K., eds., Progress on Geoenvironmental Models for Selected Mineral Deposit Types: U.S. Geological Survey Open-File Report 02-0195, p. 8-54. (Available online at http://pubs.usgs.gov/of/2002/of02-195/) Jambor, J.L., and Blowes, D.W., 1998, Theory and applications of mineralogy in environmental studies of sulfide-bearing mine wastes, in Modern Approaches to Ore and Environmental Mineralogy. Short Course Handbook, Vol. 27. Ottawa, Ontario: Mineralogical Association of Canada. p. 367-401. Kimball, B.A., 1997, Use of tracer injections and synoptic sampling to measure metal loading from acid mine drainage: U.S. Geological Survey Fact Sheet 245-96, 4 p. (Available online at http://ut.water.usgs.gov/publications/fs245-96/) Kimball B.A., Runkel R.L., Walton-Day K., and Bencala K.E., 2002, Assessment of metal loads in watersheds affected by acid mine drainage by using tracer injection and synoptic sampling: Cement Creek, Colorado, USA: Appl. Geochem., v. 17, p. 1183–1207. Kimball, B.A., Walton-Day, K., and Runkel, R.L., 2007, Quantification of metal loading by tracer injection and synoptic sampling, 1996–2000, chap. E9, in Integrated Investigations of Environmental Effects of Historical Mining in the Animas River Watershed, San Juan County, Colorado. Edited by S.E. Church, P. von Guerard, and S.E. Finger. U.S. Geological Survey Professional Paper 1651. (Available online at http://pubs.usgs.gov/pp/1651/) Kwong, Y.T.J., 1993, Prediction and Prevention of Acid Rock Drainage from a Geological and Mineralogical Perspective. MEND Project 1.32.1. Ottawa, Canada: Environment Canada. 47 p. (Available online at www.mend-nedem.org/reports/files/1.32.1.pdf) Langmuir, D., and Mahoney, J.J., 1984, Chemical equilibrium and kinetics of geochemical processes in ground water studies, in B. Hitchon and E. Wallick, eds., Practical applications of ground water geochemistry: National Water Well Association, Dublin, Ohio, p. 69–95. Lee, L., and Helsel, D., 2005, Baseline models of trace elements in major aquifers of the United States: Applied Geochemistry, v. 20, p. 1560–1570, doi:10.1016/j.apgeochem.2005.03.008. Maest, A.S., Kuipers, J.R., Travers, C.L., and Atkins, D.A., 2005, Predicting water quality at hardrock mines: methods and models, uncertainties, and state-of the-art: Buka Environmental and Kuipers & Associates, 77 p. (Available online at http://www.earthworksaction.org/library/detail/predicting_water_quality_at_hardrock_mi nes) McLemore, V.T., Russell, C.C., Smith, K.S., and the Sampling and Monitoring Committee of the Acid Drainage Technology Initiative-Metal Mining Sector (ADTI-MMS), 2004, Sampling and monitoring for closure, in Proceedings, Society for Mining, Metallurgy, and Exploration, Preprint No. 04-62, 7 p. McLemore, V.T., Smith, K.S., Russell, C.C., and the Sampling and Monitoring Committee of the Acid Drainage Technology Initiative-Metal Mining Sector (ADTI-MMS), 2007, Sampling and monitoring for closure, Chapter 11, in DeGraff, J.V., ed., Reviews in Engineering Geology, v. 17, Understanding and Responding to Hazardous Substances at Mine Sites in the Western United States: Geological Society of America, p. 171-180. (doi:10.1130/2007.4017(11)) McLemore, V.T., Russell, C.C., and Smith, K.S., 2009, ADTI-MMS sampling and monitoring for the mine-life cycle, in Proceedings of Securing the Future and 8th International Conference on Acid Rock Drainage (ICARD), Skellefteå, Sweden, June 22-26, 2009, 10 p. (Available online at http://www.proceedings-stfandicard- 2009.com/pdfer/Virginia_McLemore_B4_T3_ADTI-MMS-Sampling-and-Monitoring- for-the-Mine-life-Cycle.pdf) Nagorski, S.A., Moore, J.N., McKinnon, T.E., and Smith, D.B., 2003, Scale-dependent temporal variations in stream water geochemistry: Environ. Sci. Technol., v. 37, p. 859-864. Nimick, D.A., Gammons, C.H., Cleasby, T.E., Madison, J.P., Skaar, D., and Brick, C.M., 2003, Diel cycles in dissolved metal concentrations in streams: occurrence and possible causes: Water Resour. Res., v. 39, p. 1247. Nimick, D.A., Gammons, C.H., and Parker, S.R., 2011, Diel biogeochemical processes and their effect on the aqueous chemistry of streams: A review: Chemical Geology, v. 283, p. 3-17. Nordstrom, D.K., 2004, Modeling low-temperature geochemical processes, in J.I. Drever (Editor), Surface and Ground Water, Weathering, and Soils: Treatise on Geochemistry, Elsevier, Amsterdam, pp. 37-72. Nordstrom, D.K., 2011, Hydrogeochemical processes governing the origin, transport, and fate of major and trace elements from mine wastes and mineralized rock to surface waters: Applied Geochemistry, v. 26, p. 1777-1791. Parbhakar, A., Edraki, M., Bradshaw, D., and Walters, S., 2009, Development of mineralogical characterisation techniques for predicting Acid Rock Drainage: a case study from an abandoned Au-mine, North Australia, in Proceedings of the Eighth International Conference on Acid Rock Drainage (ICARD 8), Skellefteå, Sweden, June 23-26. Pitard, F.F., 1993, Pierre Gy's sampling theory and sampling practice (2nd ed.): Boca Raton, Florida, CRC Press, 488 p. Plumlee, G.S., Smith, K.S., Montour, M.R., Ficklin, W.H., and Mosier, E.L., 1999, Geologic controls on the composition of natural waters and mine waters draining diverse mineral- deposit types, Chapter 19, in Filipek, L.H., and Plumlee, G.S., eds., The environmental geochemistry of mineral deposits, Part B: Case studies and research topics, Reviews in Economic Geology, Vol. 6B: Littleton, Colorado, Society of Economic Geologists, Inc., p. 373-432. Price, W.A., 2005, List of potential information requirements in metal leaching and acid rock drainage assessment and mitigation work, MEND Report 5.10E: Ottawa, Natural Resources Canada, 23 p. (Available online at http://www.mend- nedem.org/reports/details-e.aspx?pub_id=5.10E) Price, W.A., 2009, Prediction Manual for Drainage Chemistry from Sulphidic Geologic Materials: MEND Report 1.20.1, Natural Resources Canada.