Page 321 - Advances In Productive, Safe, and Responsible Coal Mining
P. 321
Sustainable reclamation and water management practices 297
[17] Skousen J, Larew G. Alkaline overburden addition to acid-producing materials to prevent
acid mine drainage. International Land Reclamation and Mine Drainage Conference,
Vol. 1. Pittsburgh, PA: USDI, Bureau of Mines SP 06B-94; 1994. p. 375–81.
[18] Daniels WL, Zipper CE, Orndorff ZW, Skousen J, Barton CD, McDonald LM, Beck MA.
Predicting TDS release from central Appalachian coal mine spoils. Environ Pollut
2016;216:371–9.
[19] Hornberger R, Brady K. Chapter 7. Kinetic (leaching) tests for the prediction of mine
drainage quality. In: Coal Mine Drainage Prediction and Pollution Prevention in Penn-
sylvania. Harrisburg, PA: Pennsylvania Department of Environmental Protection; 2000.
pp. 7-1–7-54.
[20] Hornberger R, Brady K, Scheetz B, White W, Parsons S. In: ADTI-WP2 leaching column
method for overburden analysis and prediction of weathering rates. Proceedings, 2005
West Virginia mine drainage task force symposium, Morgantown, WV; 2005.
[21] Odenheimer J, Skousen J, McDonald LM, Vesper DJ, Mannix M, Daniels WL.
Predicting release of total dissolved solids from overburden material using acid-base
accounting parameters. Geochem Explor Environ Anal 2014;15:131–7.
[22] Orndorff ZW, Daniels WL, Zipper CE, Eick M. A column evaluation of Appalachian
coal mine spoils’ temporal leaching behavior. Environ Pollut 2015;204:39–47.
[23] Cormier SM, Wilkes SP, Zheng L. Relationship of land use and elevated ionic strength in
Appalachian watersheds. Environ Toxicol Chem 2013;32:296–303.
[24] Evans DM, Zipper CE, Donovan PF, Daniels WL. Long-term trends of specific conduc-
tance in waters discharged by coal-mine valley fills in central Appalachia, USA. J Am
Water Resour Assoc 2014;50:1449–60.
[25] Ross MR, McGlynn BL, Bernhardt ES. Deep impact: Effects of mountaintop mining on
surface topography, bedrock structure, and downstream waters. Environ Sci Technol
2016;50:2064–74.
[26] Toy TJ, Chase WR. Topographic reconstruction: a geomorphic approach. Ecol Eng
2005;24:29–35.
[27] Nicolau JM. Trends in relief design and construction in opencast mining reclamation.
Land Degrad Dev 2003;14:215–26.
[28] Rosgen D. Rosgen geomorphic channel design. Part 654 Stream Restoration Design,
National Engineering Handbook. Washington, DC: USDA, Natural Resources Conser-
vation Service. U.S. Govt Printing Doc.; 2007.
[29] Palmer M, Bernhardt ES, Schlesinger WH, Eshleman KN, Foufoula-Georgiou E,
Hendryx MS, Lemly AD, Likens GE, Loucks OL, Power ME, White PS,
Wilcock PR. Mountaintop mining consequences. Science 2010;327:148–9.
[30] Krenz RJ. Organic matter processes of constructed streams and associated riparian areas
in the coalfields of Southwest Virginia. Ph.D. Dissertation, Blacksburg: Virginia Tech;
2015.
[31] Skousen J, Zipper C, Burger J, Barton C, Angel P. Selecting materials for mine soil con-
struction when establishing forests on Appalachian mine sites. U.S. Office of Surface
Mining, Appalachian Regional Reforestation Initiative; 2011. Forest Reclamation Advi-
sory No. 8. Available at, http://arri.osmre.gov/.
[32] Zipper C, Burger J, Barton C, Skousen J. Rebuilding soils on mined land for native forests
in Appalachia, USA. Soil Sci Soc Am J 2013;77:337–49.
[33] Evans DM, Zipper CE, Hester ET, Schoenholtz SH. Hydrologic effects of surface coal
mining in Appalachia (U.S.). J Am Water Resour Assoc 2015;51:1436–52.
[34] Skousen J, Rose A, Geidel G, Foreman J, Evans R, Hellier W. Handbook of technologies
for avoidance and remediation of acid mine drainage. Acid Drainage Technology
