268                          Advances in Productive, Safe, and Responsible Coal Mining

          [8] US EPA. Coal ash reuse, https://www.epa.gov/coalash/coal-ash-reuse; 2018. Accessed 16
             May 2018.
          [9] Lefticariu L. Field demonstration of alternative coal processing waste disposal
             technology. Illinois Clean Coal Institute; 2014 [Final Technical Report, Project No.
             12/4C-5].
         [10] Spearing AJS. The conceptual design and financial implications of a room and pillar mine
             using paste backfilling. Illinois Clean Coal Institute; 2013 [Final Technical Report, Project
             No. 12/3A-1].
         [11] Karfakis MG, Bowman CH, Topus E. Characterization of coal-mine refuse as backfilling
             material. Geotech Geol Eng 1996;14(2):129–50.
         [12] Bayar T. Managing coal ash. Power Eng Int 2015;23(3):14–6.
         [13] Kaufman R. Seekingasaferfutureforelectricity’scoalashwaste,NationalGeographicNews
             2011;  https://news.nationalgeographic.com/news/energy/2011/08/110815-safer-ways-to-
             reycle-fly-ash-from-coal/. Accessed 16 May 2018.
         [14] ACAA. Frequently asked questions about coal ash, https://www.acaa-usa.org/
             aboutcoalash/ccpfaqs.aspx; 2018. Accessed 16 May 2018.
         [15] National Research Council. Coal waste impoundments: risks, responses, and alternatives.
             National Academy Press; 2002. http://nap.edu/10212. Accessed 16 May 2018.
         [16] American Society for Testing and Materials (ASTM). ASTM D698-12e1: standard test
             methods for laboratory compaction characteristics of soil using standard effort
                                  3
             (12400ft-lbf/ft3(600kN-m/m )), In: Book of standards. vol. 04.08. 2013. http://www.
             astm.org/Standards/D698.htm. Accessed 16 May 2018.
         [17] Chugh YP, Mohanty S, Behum PT, Nawrot J, Bell W, Chen S. Best management practices
             to minimize sulfate and chloride discharges. Illinois Clean Coal Institute; 2007 [Final
             Technical Report, Project No. DEV05-8].
         [18] Parekh BK. Dewatering of fine coal and refuse slurries—problems and possibilities, Proc
             Earth Planet Sci 2009;1(1):621–6. [Accessed 18 May 2018]. https://doi.org/10.1016/j.
             proeps.2009.09.098.
         [19] Patil DP, Honaker RQ, Parekh BK. Paste thickening of fine coal refuse. Int J Coal Prep Util
             2007;27(4):191–209.
         [20] Meiring S. Thickener versus centrifuges—a coal tailings technical comparison,
             In: Proceedings, paste 2015. 2015. https://papers.acg.uwaedu.au/p/1504_02_Meiring/.
             Accessed 18 May 2018.
         [21] Rajagopalan N, Salih H, Patel VA. Fine refuse and ultrafine coal dewatering utilizing an
             osmotic gradient. Illinois Clean Coal Institute; 2014 [Final Technical Report, Project No.
             13/4C-1].
         [22] Klima MS, Arnold BJ, Munjack J, Barry B. Application of a pilot-scale plate filter press in
             dewatering coal slurries. In: Craynon JR, editor. Environmental considerations in energy
             production. Englewood, CO: Society for Mining, Metallurgy, and Exploration (SME);
             2013. p. 42–50.
         [23] Chugh YP. Underground placement of coal processing waste and coal combustion
             by-products based paste backfill for enhanced mining economics. Illinois Clean Coal Insti-
             tute; 2001 [Final Technical Report, Project No. 97US-1].
         [24] Spearing AJS. The use of tailings in underground coal mines in the USA. Illinois Clean
             Coal Institute; 2010 [Final Technical Report, Project No. 08-1/US-6].
         [25] Rohatgi PK, Weiss D, Gupta N. Applications of fly ash in synthesizing low-cost MMCs for
             automotive and other applications. JOM 2006;58(11):71–6.