Maksimovich N.G., Meshcheriakova O.Yu., Berezina O.A., 2022. Influence of the discharge of acid mine waters on karst dry valleys of the Kizel coal basin. Engineering Geology World, Vol. XVII, No. 3, pp. 30–43, https://doi.org/10.25296/1993-5056-2022-17-3-30-43.
1. Andreichuk V.N., Benderov A.D., 1991. Regional features of anthropogenic impact on karst in mountainous countries. Publishing house of the Ural Branch of the USSR Academy of Sciences, Sverdlovsk. (in Russian)
2. Bunina M.V., 1947. Karst phenomena in the deposits of the Visean stage within the fields of mines 6 and 15 of the Kizel coal basin. Abstracts of the Molotov karst Conference, Molotov, 1947, pp. 5–8. (in Russian)
3. Gerasimova I.Yu., Shvetsova O.O., Zavorokhin A.F., Chirkov E.M., 2018. Caves of the Gubakhinsky speleosubarea. In collection of scientific papers Caves, Issue 41. Publishing house of the Perm University, Perm, pp. 46–62. (in Russian)
4. Gorbunova K.A., Andreichuk V.N., Kostarev V.P., Maksimovich N.G., 1992. Karst and caves of the Perm Region. Publishing house of the Perm University, Perm. (in Russian)
5. Guldenbalk V.P., 1947. Peculiarities of the regime of karst waters under the conditions of their drainage in the Kizel coal region. Abstracts of the Molotov karst Conference, Molotov, 1947, pp. 21–25. (in Russian)
6. Ezhov Yu.A., 1962. Karst and hydrogeology of the Kizel coal-bearing region in connection with the development of deep horizons of deposits. PhD Thesis, Kungur Station of the Institute of Geology, Ural Branch, USSR Academy of Sciences, Kungur. (in Russian)
7. Krasavin A.P., Safin R.T., 2005. Ecological rehabilitation of coal mining areas of the Kizel coal basin in connection with the closure of mines. Zvezda, Perm. (in Russian)
8. Krotova E.A., 1956. Karst landforms. Uchenyye Zapiski: Geologiya i Geografiya, Vol. 10, Issue 2, pp. 5–10. (in Russian)
9. Maksimovich G.A., 1969. Fundamentals of karst studies. Vol. 2. Questions of hydrogeology of karst, rivers and lakes of karst regions, chalk karst, hydrothermokarst. Publishing house of the Perm University, Perm. (in Russian)
10. Maksimovich N.G., Berezina O.A., Meshcheriakova O.Yu., Demenev A.D., 2020. Research of migration of technogenic bottom sediments with application of modern geoinformation systems. Geoinformation support for sustainable development of territories, Materials of the International Conference “InterCarto. InterGIS”, Vol. 26, Part 2, Tashkent (Uzbekistan) — Pyatigorsk (Russia) — Tbilisi (Georgia), 2020, pp. 201–211, https://doi.org/10.35595/2414-9179-2020-2-26-201-211. (in Russian)
11. Maksimovich N.G., Pyankov S.V., 2018. Kizel coal basin: environmental problems and solutions. Publishing house of the Perm University, Perm. (in Russian)
12. Rodionov N.V., 1963. Karst of the European part of the USSR, the Urals, and the Caucasus. Gosgeoltekhizdat, Moscow. (in Russian)
13. Rybnikov P.A., Rybnikova L.S., Maksimovich N.G., Demenev A.D., 2020. Hydrogeology of the Kizel Coal Basin (Western Urals, Russia) in post-mining stage: the main problems and ways of their solution. Mining Informational and Analytical Bulletin, No. 3(1), pp. 475–487, https://doi.org/10.25018/0236-1493-2020-31-0-475-487. (in Russian)
14. Ryzhikov D.V., 1954. The nature of karst and the main patterns of its development (a case of the Urals). Publishing house of the USSR Academy of Sciences, Moscow. (in Russian)
15. Sergeev V.I., Savenko A.V., Gato L., 2000. Use of calcarenite for the removal of heavy metals from waters containing dissolved organic matter. Geoekologiya, No. 3, рр. 229–233. (in Russian)
16. Smirnov A.I., Abdrakhmanov R.F., Durnaeva V.N., 2019. Types of karst and features of its distribution in the Southern Urals and in the Cis-Urals. Geologicheskiy Vestnik, No. 2, pp. 111–124, http://doi.org/10.31084/2619-0087/2019-2-9. (in Russian)
17. Yurgenson G.A., 2005. Landscape geochemistry. Publishing house of the Transbaikal State Humanitarian Pedagogical University, Chita. (in Russian)
18. Alekseenko V.A., Maximovich N.G., Alekseenko A.V., 2017. Chapter 9. Geochemical barriers for soil protection in mining areas. In
J. Bech, C. Bini, M.A. Pashkevich (eds), Assessment, restoration and reclamation of mining influenced soils. Academic Press, London,
pp. 255–274, https://doi.org/10.1016/B978-0-12-809588-1.00009-8.
19. Baker B.J., Banfield J.F., 2003. Microbial communities in acid mine drainage. FEMS Microbiology Ecology, Vol. 44, Issue 2,
pp. 139–152, https://doi.org/10.1016/S0168-6496(03)00028-X.
20. Berezina O.A., Maksimovich N.G., Pyankov S.V., 2018. Hydroecological characteristic of coal-mining regions with crucial anthropogenic load (in the case study of the Yaiva river basin). IOP Conference Series: Earth and Environmental Science, Vol. 107, ID 012001, https://doi.org/10.1088/1755-1315/107/1/012001.
21. Brake S.S., Connors K.A., Romberger S.B., 2001. A river runs through it: impact of acid mine drainage on the geochemistry of West Little Sugar Creek pre- and post-reclamation at the Green Valley coal mine, Indiana, USA. Environmental Geology, Vol. 40, pp. 1471–1481, https://doi.org/10.1007/s002540100373.
22. Ford D.C., Williams P.W., 1989. Karst geomorphology and hydrogeology. Springer, Dordrecht, The Netherlands.
23. Huang H., Chen Z., Wang T., Zhang L., Liu T., Zhou G., 2021. Pattern and degree of groundwater recharge from river leakage in a karst canyon area under intensive mine dewatering. Science of the Total Environment, Vol. 774, ID 144921, https://doi.org/10.1016/j.scitotenv.2020.144921.
24. Jonathan D.P., 2017. Landform transitions in a fuviokarst landscape. Zeitschrift für Geomorphologie, Vol. 61, Issue 2, pp. 109–122, https://doi.org/10.1127/zfg/2017/0452.
25. Khayrulina E., Khmurchik V., Maksimovich N., 2016. The Kizel coal basin (the Western Urals, Russia): environmental problems and solutions. Mining meets water — conflicts and solutions, Proceedings of the IMWA 2016 Annual Conference, Freiberg, Germany, 2016, pp. 761–767.
26. Masferrer J.A.R., 2002. Passive treatment of acid mine drainage at the La Extranjera mine (Puertollano, Spain). Mine Water Environment, Vol. 21, pp. 111–113, https://doi.org/10.1007/s102300200031.
27. Matess G., Otting R., Schulz M., Werner H., 1982. Effect of coal mine waters of Nordrhine-Westpalia in groundwater. Jans Publications, Vol. 139, pp. 271–278.
28. Maximovich N., 2006. Use of alkaline waste products for acid mine water purification. Engineering geology for tomorrow’s cities, Abstracts of 10th Congress of the International Association for Engineering Geology and the Environment, Nottingham, UK, 2006,
pр. 6–10.
29. Maximovich N., Khayrulina E., 2014. Artificial geochemical barriers for environmental improvement in a coal basin region. Environmental Earth Sciences, Vol. 72, No. 6, pp. 1915–1924, https://doi.org/10.1007/s12665-014-3099-7.
30. Panoš V., 2001. Karsologická a speleologická terminologie. Knižné Centrum, Žilina, Czech Republic. (in Czech)
31. Powell J.D., 1988. Origin and influence of coal mine drainage on streams of the United States. Environmental Geology and Water Sciences, Vol. 11, pр. 141–152, https://doi.org/10.1007/BF02580450.
32. Siddharth S., Jamal A., Dhar B.B., Shukla R., 2002. Acid-base accounting: a geochemical tool for management of acid drainage in coal mines. Mine Water and the Environment, Vol. 21, pp. 106–110, https://doi.org/10.1007/s102300200030.
33. Tao X., Wu P., Tang C., Liu H., Sun J., 2012. Effect of acid mine drainage on a karst basin: a case study on the high-As coal mining area in Guizhou province, China. Environmental Earth Sciences, Vol. 65, pp. 631–638, https://doi.org/10.1007/s12665-011-1110-0.
34. Tiwary R.K., Dhar B.B., 1994. Environmental pollution from coal mining activities in Damodar River Basin, India. Mine Water and the Environment, Vol. 13, pp. 1–10.
35. Wiggering H., 1986. Verwitterung auf Steinkohlenbergehalden; ein erster schritt von anthropo-technogenen eingriffen zuruck in den naturlichen exogengeodynamischen kreislauf der gesteine. Zeitschrift der Deutschen Gesellschaft für Geowissenschaften, Vol. 137, No. 2, pp. 431–446, https://doi.org/10.1127/zdgg/137/1986/431.
36. Xu S., Lang Y., Zhong J., Xiao M., Ding H., 2020. Coupled controls of climate, lithology and land use on dissolved trace elements in a karst river system. Journal of Hydrology, Vol. 591, ID 125328, https://doi.org/10.1016/j.jhydrol.2020.125328.
37. Zhang H., Xu G., Chen X., Mabaire A., Zhou J., Zhang Y., Zhang G., Zhu L., 2020. Groundwater hydrogeochemical processes and the connectivity of multilayer aquifers in a coal mine with karst collapse columns. Mine Water Environment, Vol. 39, pp. 356–368, https://doi.org/10.1007/s10230-020-00667-w.