МИКРОБНЫЕ СООБЩЕСТВА ПРИРОДНОГО ОРНАНИЧЕСКОГО ВЕЩЕСТВА ИЗ ПОТОКА РАССЕЯНИЯ ВЫСКОКСУЛЬФИДНОГО ХВОСТОХРАНИЛИЩА

1. Aguilera A, Olsson S, Puente-Sa´ nchez F: Physiological and phylogenetic diversity of acidophilic eukaryotes. In Acidophiles: Life in Extremely Acidic Environments. Edited by Quatrini R, Johnson DB. Caister Academic Press;2016:107-118

2. Hedrich, S., Schippers, A. (2016). Distribution of acidophilic microorganisms in natural and man-madeacidic enviroments. Acidophiles: Life in Extremely Acidic Environments, 153-175.

3. Johnson, D.B., Quatrini-Nyqvist, R.C. (2016). Acidophile Microbiology in Space and Time.

4. Kuimova N.G., Pavlova L.M., Sorokin A.P., Noskova L.P., Sergeeva A.G. (2011). Experimental modeling of gold concentrating processes in peat. Litosfera 4, 131-136.

5. Lazareva E.V., Myagkaya I.N., Kirichenko I.S., Gustaytis M.A., Zhmodik S.M. (2019). Interaction of natural organic matter with acid mine drainage: In-situ accumulation of elements. Science of the Total Environment 660, 468-483.

6. Myagkaya I.N., Lazareva E.V., Gustaitis M.A., Zhmodik S.M. (2016). Gold and silver in a system of sulfide tailings. Part 1: Migration in water flow. Journal of Geochemical Exploration 160, 16-30.

7. Myagkaya I.N., et al. (2020). Interaction of natural organic matter with acid mine drainage: Authigenic mineralization (case study of Ursk sulfide tailings, Kemerovo region, Russia). Journal of Geochemical Exploration 211, 106456.

8. Parviainen A. et al.. (2014). Pre-miningacid rock drainage in the Talvivaara Ni-Cu-Zn-Co deposit (Finland): Natural peat layers as a natural analog to constructed wetlands. Journal of Geochemical Exploration 143, 84-95.

9. Rozanov, A.S. et al. (2014). Molecular analysis of the benthos microbial community in Zavarzin thermal spring (Uzon Caldera, Kamchatka, Russia).BMC genomics, 15(12), S12.

10. Teng, W., Kuang, J., Luo, Z., Shu, W. (2017). Microbial diversity and community assembly across environmental gradients in acid mine drainage. Minerals, 7(6), 106.