296                          Advances in Productive, Safe, and Responsible Coal Mining

         References


          [1] Skousen JG, Zipper CE. Post-mining policies and practices in the Eastern USA coal
             region. Int J Coal Sci Technol 2014;1:135–51.
          [2] United States Environmental Protection Agency (US EPA). Water Quality Criteria,
             https://www.epa.gov/wqc; 2016.
          [3] American Public Health Association (APHA). Standard Methods for the Examination of
             Water and Wastewater.
          [4] Timpano AJ, Schoenholtz SH, Soucek DJ, Zipper CE. Salinity as a limiting factor for bio-
             logical condition in mining-influenced Central Appalachian headwater streams. J Am
             Water Resour Assoc 2015;51:240–50.
          [5] Daniels WL, Orndorff ZW, Zipper CE. Predicting release and aquatic effects of total dis-
             solved solids from Appalachian USA coal mines. Int J Coal Sci Technol 2014;1:152–62.
          [6] Pond GJ, Passmore ME, Borsuk FA, Reynolds L, Rose CJ. Downstream effects of moun-
             taintop coal mining: comparing biological conditions using family- and genus-level
             macroinvertebrate bioassessment tools. J North Am Benthol Soc 2008;27:717–37.
          [7] U.S. Environmental Protection Agency (US EPA). A field-based aquatic life benchmark
             for conductivity in central Appalachian streams. EPA600-R-10-023F, Washington, DC:
             National Center for Environmental Assessment, Office of Research and Development;
             2011.
          [8] Presser TS, Luoma SN. A methodology for ecosystem-scale modeling of selenium. Integr
             Environ Assess Manage 2010;6:685–710.
          [9] United States Environmental Protection Agency (US EPA). Water Quality Criteria.
             Aquatic Life Ambient Water Quality Criterion for Selenium – Freshwater 2016. Office
             of Water; 2016. EPA 822-R-16-006.
          [10] Skousen J. A methodology for geologic testing for land disturbance: acid-base account-
              ing for surface mines. Geoderma 2017;308:302–11.
          [11] Skousen JG, Sencindiver JC, Smith RM. A review of procedures for surface mining and
              reclamation in areas with acid-producing materials. Morgantown, WV: National
              Research Center for Coal and Energy, National Mine Land Reclamation Center; 1987.
          [12] Geidel G, Caruccio FT, Hornberger R, Brady K. Chapter 5: Guidelines and recommen-
              dations for use of kinetic tests for coal mining (AMD) prediction in the eastern US.
              In: Kleinmann R, editor. Prediction of water quality at surface coal mines.
              Morgantown, WV: Acid Drainage Technology Initiative (ADTI), National Mine Land
              Reclamation Center; 2000.
          [13] Skousen J, Perry E, Leavitt B, Sames G, Chisholm W, Cecil C, Hammack R,
              Kleinmann R. Chapter 4: Static tests for coal mining acid mine drainage prediction in
              the eastern US. In: Prediction of Water Quality at Surface Coal Mines. Acid Drainage
              Technology Initiative (ADTI). Morgantown, WV: National Mine Land Reclamation
              Center; 2000.
          [14] Skousen J, Simmons J, Ziemkiewicz P. Acid-base accounting to predict post-mining
              drainage quality on surface mines. J Environ Qual 2002;31:2034–44.
          [15] Sobek AA, Skousen JG, Fisher Jr. SE. Chemical and physical properties of overburdens
              and minesoils. In: Barnhisel R, Darmody R, Daniels W, editors. Reclamation of Drasti-
              cally Disturbed Lands. Madison, WI: American Society of Agronomy; 2000. p. 77–104.
              Agronomy Monograph No. 41.
          [16] Skousen J, Renton J, Brown H, Evans P, Leavitt B, Brady K, Cohen L, Ziemkiewicz P.
              Neutralization potential of overburden samples containing siderite. J Environ Qual
              1997;26:673–81.