Siddique, R. Utilization of coal combustion by-products in sustainable construction materials. Resour. Conserv. Recycl. 54, 1060–1066 (2010).
Querol, X., Juan, R., Lopez-Soler, A., Fernandez-Turiel, J. & Ruiz, C. Mobility of trace elements from coal and combustion wastes. Fuel 75, 821–838 (1996).
Kalkreuth, W. et al. Evaluation of environmental impacts of the Figueira coal-fired power plant, Paraná, Brazil. Energ. Explor. Exploit. 32, 423–469 (2014).
MacBride, S. The archeology of coal ash: An industrial-urban solid waste at the dawn of the hydrocarbon economy. IA. Soc. Ind. Archeol. 39, 23–39 (2013).
Matzenbacher, C. et al. DNA damage induced by coal dust, fly and bottom ash from coal combustion evaluated using the micronucleus test and comet assay in vitro. J. Hazard. Mater. 324, 781–788 (2017).
Messinger, M. & Silman, M. Unmanned aerial vehicles for the assessment and monitoring of environmental contamination: An example from coal ash spills. Environ. Pollut. 218, 889–894 (2016).
Santamarina, J., Torres-Cruz, L. & Bachus, R. Why coal ash and tailings dam disasters occur. Science 364, 526–528 (2019).
Ruhl, L. et al. Survey of the potential environmental and health impacts in the immediate aftermath of the coal ash spill in Kingston, Tennessee. Environ. Sci. Technol. 43, 6326–6333 (2009).
Vengosh, A. et al. Evidence for unmonitored coal ash spills in Sutton Lake, North Carolina: Implications for contamination of lake ecosystems. Sci. Total Environ. 686, 1090–1103 (2019).
Ramsey, A., Faiia, A. & Szynkiewicz, A. Eight years after the coal ash spill: Fate of trace metals in the contaminated river sediments near Kingston, eastern Tennessee. Appl. Geochem. 104, 158–167 (2019).
Schwartz, G. et al. Leaching potential and redox transformations of arsenic and selenium in sediment microcosms with fly ash. Appl. Geochem. 67, 177–185 (2016).
Giam, X., Olden, J. & Simberloff, D. Impact of coal mining on stream biodiversity in the US and its regulatory implications. Nat. Sustain. 1, 176–183 (2018).
Kravchenko, J. & Lyerly, H. The impact of coal-powered electrical plants and coal ash impoundments on the health of residential communities. N. C. Med. J. 79, 289–300 (2018).
Greeley, M., Adams, S., Elmore, L. & McCracken, M. Influence of metal(loid) bioaccumulation and maternal transfer on embryo-larval development in fish exposed to a major coal ash spill. Aquat. Toxicol. 173, 165–177. https://doi.org/10.1016/j.aquatox.2015.12.021 (2016).
Lemly, A. Environmental hazard assessment of coal ash disposal at the proposed Rampal power plant. Hum. Ecol. Risk Assess. 24, 627–641 (2018).
Puc, D. Divaška Jama (Občina Divača, 1999).
Batty, L. The potential importance of mine sites for biodiversity. Mine Water Environ. 24, 101–103 (2005).
Luo, Z. et al. Adaptive development of soil bacterial communities to ecological processes caused by mining activities in the Loess Plateau, China. Microorganisms 8, 477 (2020).
Thavamani, P. et al. Microbes from mined sites: Harnessing their potential for reclamation of derelict mine sites. Environ. Pollut. 230, 495–505 (2017).
Apostolova, D., Bechtel, A., Kostova, I. & Stefanova, M. Biomarkers assemblage of unburned coal particles in fly ashes from Bulgarian thermoelectric power plants. J. Min. Geol. Sci. 63, 203–206 (2020).
Cui, Y. et al. Stoichiometric models of microbial metabolic limitation in soil systems. Global Ecol. Biogeogr. 30, 2297–2311 (2021).
Dean, W. Determination of carbonate and organic matter in calcareous sediments and sedimentary rocks by loss on ignition: comparison with other methods. J. Sediment. Petrol. 44, 242–248 (1974).
MacDonald, D., Ingersoll, C. & Berger, T. Development and evaluation of consensus-based sediment quality guidelines for freshwater ecosystems. Arch. Environ. Contam. Toxicol. 39, 20–31 (2000).
Milačič, R., Zuliani, T., Vidmar, J., Oprčkal, P. & Ščančar, J. Potentially toxic elements in water and sediments of the Sava River under extreme flow events. Sci. Total Environ. 605, 894–905 (2017).
Vidmar, J. et al. Elements in water, suspended particulate matter and sediments of the Sava River. J. Soils Sediments 17, 1917–1927 (2017).
Oprčkal, P. et al. Remediation of contaminated soil by red mud and paper ash. J. Clean. Prod. 256, 120440 (2020).
Nisnevich, M., Sirotin, G., Schlesinger, T. & Eshel, Y. Radiological safety aspects of utilizing coal ashes for production of lightweight concrete. Fuel 87, 1610–1616 (2008).
Komonweeraket, K., Cetin, B., Benson, C., Aydilek, A. & Edil, T. Leaching characteristics of toxic constituents from coal fly ash mixed soils under the influence of pH. Waste Manage. 38, 174–184 (2015).
Popovic, A. & Djordjevic, D. pH-dependent leaching of dump coal ash: Retrospective environmental analysis. Energ. Source Part A 31, 1553–1560 (2009).
Mori, N., Simčič, T., Žibrat, U. & Brancelj, A. The role of river flow dynamics and food availability in structuring hyporheic microcrustacean assemblages: A reach scale study. Fundam. Appl. Limnol. 180, 335–349 (2012).
de Vicente, I., Amores, V., Guerrero, F. & Cruz-Pizarro, L. Contrasting factors controlling microbial respiratory activity in the sediment of two adjacent Mediterranean wetlands. Naturwissenschaften 97, 627–635 (2010).
Mori, N., Simčič, T., Brancelj, A., Robinson, C. & Doering, M. Spatiotemporal heterogeneity of actual and potential respiration in two contrasting floodplains. Hydrol. Process. 31, 2622–2636 (2017).
Muri, G. & Simčič, T. Respiratory activity in sediments of three mountain lakes in the Julian Alps and in subalpine Lake Bled (Slovenia): Effects of altitude and anthropic influence. Aquat. Microb. Ecol. 34, 291–299 (2004).
Broberg, A. Effects of heavy metals on electron transport system activity (ETSA) in freshwater sediments. Ecol. Bull. 35, 403–418 (1983).
Aljerf, L. & AlMasri, N. A gateway to metal resistance: Bacterial response to heavy metal toxicity in the biological environment. AAC 2, 32–44 (2018).
Robbens, J., Dardenne, F., Devriese, L., De Coen, W. & Blust, R. Escherichia coli as a bioreporter in ecotoxicology. Appl. Microbiol. Biotechnol. 88, 1007–1025 (2010).
Abbas, M. et al. Vibrio fischeri bioluminescence inhibition assay for ecotoxicity assessment: A review. Sci. Total Environ. 626, 1295–1309 (2018).
Prabhakaran, P., Ashraf, M. & Aqma, W. Microbial stress response to heavy metals in the environment. RSC Adv. 6, 109862–109877 (2016).
Hughes, M. Arsenic toxicity and potential mechanisms of action. Toxicol. Lett. 133, 1–16 (2002).
Cervantes, C. et al. Interactions of chromium with microorganisms and plants. FEMS Microbiol. Rev. 25, 335–347 (2001).
Ladomersky, E. & Petris, M. Copper tolerance and virulence in bacteria. Metallomics 7, 957–964 (2015).
Miller, D. & Woods, J. Redox activities of mercury-thiol complexes: Implications for mercury-induced porphyria and toxicity. Chem Biol. Interact. 88, 23–35 (1993).
Macomber, L. & Hausinger, R. Mechanisms of nickel toxicity in microorganisms. Metallomics 3, 1153–1162 (2011).
Lopes, A., Peixe, T., Mesas, A. & Paoliello, M. in Reviews of Environmental Contamination and Toxicology. 236 193–238 (Springer, 2016).
Valko, M., Morris, H. & Cronin, M. Metals, toxicity and oxidative stress. Curr. Med. Chem. 12, 1161–1208 (2005).
Simon, K., Pipan, T. & Culver, D. A conceptual model of the flow and distribution of organic carbon in caves. J. Cave Karst Stud. 69, 279–284 (2007).
Mulec, J. & Oarga-Mulec, A. ATP luminescence assay as a bioburden estimator of biomass accumulation in caves. Int. J. Speleol. 45, 207 (2016).
Gerič, B., Pipan, T. & Mulec, J. Diversity of culturable bacteria and meiofauna in the epikarst of Škocjanske jame Caves (Slovenia). Acta Carsol. 33, 301–309 (2004).
Adibee, N., Osanloo, M. & Rahmanpour, M. Adverse effects of coal mine waste dumps on the environment and their management. Environ. Earth Sci. 70, 1581–1592 (2013).
Jing, R. & Kjellerup, B. Biogeochemical cycling of metals impacting by microbial mobilization and immobilization. J. Environ. Sci. 66, 146–154 (2018).
Huang, J. Arsenic trophodynamics along the food chains/webs of different ecosystems: A review. Chem. Ecol. 32, 803–828 (2016).
Cempel, M. & Nikel, G. Nickel: A review of its sources and environmental toxicology. Pol. J. Environ. Stud. 15 (2006).
Rimmer, C., Miller, E., McFarland, K., Taylor, R. & Faccio, S. Mercury bioaccumulation and trophic transfer in the terrestrial food web of a montane forest. Ecotoxicology 19, 697–709 (2010).
Fernández, P., Viñarta, S., Bernal, A., Cruz, E. & Figueroa, L. Bioremediation strategies for chromium removal: Current research, scale-up approach and future perspectives. Chemosphere 208, 139–148 (2018).
Mihevc, A. Speleogeneza Divaškega Krasa. Vol. 27 180 (Založba ZRC, 2001).
Žvab Rožič, P., Čar, J. & Rožič, B. Geological structure of the Divača area and its influence on speleogenesis and hydrogeology of Kačna jama. Acta Carsol. 44 (2015).
Zupan Hajna, N., Mihevc, A., Pruner, P. & Bosák, P. Palaeomagnetism and Magnetostratigraphy of Karst Sediments in Slovenia. Vol. 8 (Založba ZRC, ZRC SAZU, 2008).
Bosák, P., Pruner, P. & Zupan Hajna, N. Palaeomagnetic research of cave sediments in SW Slovenia. Acta Carsol. 27, 151–179 (1998).
Zbíral, J. Soil Analyses, Part 1 (in Czech). (Central Institute for Supervising and Testing in Agriculture, 1995).
Degen, T., Sadki, M., Bron, E., Konig, U. & Nenert, G. The HighScore suite. Powder Diffr. 29, S13–S18 (2014).
Chan, W., Verma, C., Lane, D. & Gan, S. A comparison and optimization of methods and factors affecting the transformation of Escherichia coli. Biosci. Rep. 33, e00086 (2013).
Kostylev, M., Otwell, A., Richardson, R. & Suzuki, Y. Cloning should be simple: Escherichia coli DH5α-mediated assembly of multiple DNA fragments with short end homologies. PLoS ONE 10 (2015).
Packard, T. The measurement of respiratory electron transport activity in marine phytoplankton. J. Mar. Res. 29, 235–244 (1971).
G.-Toth, L. in Biologische Gewässeruntersuchung. Methoden der Biologische Wasseruntersuchung 2. (eds W von Tumpling & G Friedrich) 465–473 (Gustav Fischer Verlag, 1999).
Kenner, R. & Ahmed, S. Measurements of electron transport activities in marine phytoplankton. Mar. Biol. 33, 119–127 (1975).
