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ENVIRONMENTAL PROTECTION
ArticleName Applied research and process solutions in waste water clarification and treatment in mining industry: Review
DOI 10.17580/em.2024.01.16
ArticleAuthor Raevich K. V., Vokin V. N., Kiryushina E. V., Maglinets Yu. A.
ArticleAuthorData

Siberian Federal University, Krasnoyarsk, Russia

Raevich K. V., Associate Professor, Candidate of Engineering Sciences, zenkoviv@mail.ru
Vokin V. N., Professor, Candidate of Engineering Sciences
Kiryushina E. V., Associate Professor, Candidate of Engineering Sciences
Maglinets Yu. A., Professor, Candidate of Engineering Sciences

 

The paper was written with the participation of I. V. Zenkov, Professor, Doctor of Engineering Sciences.

Abstract

The authors describe the main achievements in the sphere of recovery ecology in the mining industry, namely, in the sphere of clarification and treatment of water resources pumped out of mines or used in mineral processing. The review reveals that water treatment includes removal of both mono contaminants and a number of elements (metals and their compounds), or nonmetallic toxic compounds from water. When solving ecological problems, researchers widely use chemical, physical, electrochemical and other methods of waste water clarification and treatment. The recent ecology of water resources is collecting a new knowledge on accumulation of different metals by species of higher vascular plants, water plants, fungi and microbial communities.

keywords mining industry, mining industry ecology, water contamination, heavy metals, toxic elements, water clarification and treatment, phytoremediation
References

1. Muedi K.L., Brink H.G., Masindi V. et al. Effective removal of arsenate fromwas tewater using aluminium enriched ferric oxide–hydroxide recovered from authentic acid mine drainage. Journal of Hazardous Materials. 2021. Vol. 414. ID 125491.
2. Xu Yifan, Li Hao, Zeng Xian-Chun. A novel biofilm bioreactor derived from a consortium of acidophilic arsenite-oxidizing bacteria for the cleaning up of arsenite from acid mine drainage. Ecotoxicology. 2021. Vol. 30. pp. 1437–1445.
3. Singh Shweta, Chakraborty Saswati. Bioremediation of acid mine drainage in constructed wetlands: Aspect of vegetation (Typha latifolia), loading rate and metal recovery. Minerals Engineering. 2021. Vol. 171. ID 107083.
4. Makhanya B. N., Nyandeni N., Ndulini S. F., Mthembu M. S. Application of green microalgae biofilms for heavy metals removal from mine effluent. Physics and Chemistry of the Earth. 2021. Vol. 124. ID 103079.
5. Barthen Roberta, Sulonen Mira L. K., Peräniemi Sirpa, Jain Rohan, Lakaniemi Aino-Maija. Removal and recovery of metal ions from acidic multi-metal mine water using waste digested activated sludge as biosorbent. Hydrometallurgy. 2022. Vol. 207. ID 105770.
6. Wibowo Yudha Gustia, Sudibyo S., Naswi M, Bimastyaji Surya Ramadan. Performance of a novel biochar-clamshell composite for real acid mine drainage treatment. Bioresource Technology Reports. 2022. Vol. 17. ID 100993.
7. Rezende Moreira V., Abner Rocha Lebron Y., Gontijo D., Míriam Cristina Santos Amaral. Membrane distillation and dispersive solvent extraction in a closed-loop process for water, sulfuric acid and copper recycling from gold mining wastewater. Chemical Engineering Journal. 2022. Vol. 435, P. 2. ID 133874.
8. Zhang Yinjie, You Chang, Ren Meng. et al. Ion exchange membrane optimized light-driven photoelectrochemical unit for efficiency simultaneous organic degradation and metal recovery from the mine wastewater. Journal of Hazardous Materials. Vol. 429. ID 128352.
9. Liu Eryonga, Jing Weiqi, Zhang Xing. et al. Improved thin-film-composite forward-osmosis membrane for coal mine water purification. Materials Chemistry and Physics. 2022. Vol. 283. ID 126011.
10. Manyuchi M. M., Sukdeo N., Stinner W. Potential to remove heavy me tals and cyanide from gold mining wastewater using biochar. Physics and Chemistry of the Earth. 2022. Vol. 126. ID 103110.
11. Jacob Jérôme, Joulian Catherine, Battaglia-Brunet Fabienne. Start-up and performance of a full scale passive system in-cluding biofilters for the treatment of Fe, as and Mn in a neutral mine drainage. Water. 2022. Vol. 14, Iss. 12. ID 1963.
12. Khan A. J., Akhter G., Ge Y., Shahid M., Rahman K. U. Development of artificial geochemical filter to treat acid mine drainage for safe disposal of mine water in salt range portion of Indus basin – A lab to pilot scale study. Sustainability. 2022. Vol. 14, Iss. 13. ID 7693.
13. Zou Zh., Yang H., Zhang Sh et al. Nitrogen removal performance and microbial community analysis of immobilized biological fillers in rare earth mine wastewater. Biochemical Engineering Journal. Vol. 186. ID 108559.
14. Baena-Moreno F. M., Rodríguez-Galán M., Arroyo-Torralvo F., Vilches L. F. Low-energy method for water-mineral recovery from acid mine drainage based on membrane technology: Evaluation of inorganic salts as draw solutions. Environmental Science and Technology. 2020. Vol. 54, Iss. 17. pp. 10936–10943.
15. Mengtao Fu, Junxuan Ao, Lin Ma. et al. Uranium removal from waste water of the tailings with functional recycled plastic membrane. Separation and Purification Technology. 2022. Vol. 287. ID 120572.
16. Malygina M. A., Ayzenshtadt A. M., Korolev E. V., Drozdyuk T. A., Frolova M. A. Electrolyte coagulation of saponite bearing water suspension for reuse by mining enterprises. Ecology and Industry of Russia. 2022. Vol. 16, No. 11. pp. 27–33.
17. Gerasimov V. M., Svalova K. V., Nizhegorodtsev E. I. High-efficient treatment of circulation water in gold mines using fibrous polymeric materials. Gorniy Zhurnal. 2019. No. 12. pp. 94–97.
18. Zhanga R., Lu J., Dopson M., Leiviskäa T. Vanadium removal from mining ditch water using commercial iron products and ferric groundwater treatment residual-based materials. Chemosphere. 2022. Vol. 286, P. 2. ID 131817.
19. Longwei Yin, Wenpeng Li, Shen Lin. et al. Simultaneous removal of arsenite and arsenate from mining wastewater using ZIF-8 embedded with iron nanoparticles. Chemosphere. 2022. Vol. 304. ID 135269.
20. Elsahwi Essam S., Hopp Conrad E., Dawson Francis P. et al. Electrochemical oxidation of ammonia-laden wastewater in the mining industry. IEEE Transactions on Industry Applications. 2022. Vol. 58, Iss. 3. pp. 4225–4232.
21. Fang Difan, Yang Liming, Hu Wenbin. et al. Tandem type PRBs-like technology implanted with targeted functional materials for efficient resourceful treatment of heavy metal ions from mining wastewater. Chemical Engineering Journal. 2021. Vol. 420, P. 3. ID 130506.
22. Menzel K., Barros L., García A. et al. Metal sulfide precipitation coupled with membrane filtration process for recovering copper from acid mine drainage. Separation and Purification Technology. 2021. Vol. 270. ID 118721.
23. Liu Jiequana, Zhou Ruyia, Yu Junxia. et al. Simultaneous removal of lead, manganese, and copper released from the copper tailings by a novel magnetic modified biosorbent. Journal of Environmental Management. 2022. Vol. 322. ID 116157.
24. Ugwu E. I., Othmani A., Nnaji C. C. A review on zeolites as cost-effective adsorbents for removal of heavy metals from aqueous environment. International Journal of Environmental Science and Technology. 2022. Vol. 19. pp. 8061–8084.
25. Yang X., Osawa H., Kameda T. et al. Continuous treatment of abandoned mine wastewater containing As and Fe using Mg–Al layered double hydroxides with flocculation. International Journal of Environmental Science and Technology. 2021. Vol. 18. pp. 4037–4042.
26. Ilay R., Baba A., Kavdır Y. Removal of metals and metalloids from acidic mining lake (AML) using olive oil solid waste (OSW). International Journal of Environmental Science and Technology. 2019. Vol. 16. pp. 4047–4058.

27. Weng Fu, Guozhao Ji, Huihuang Chen. et al. Molybdenum sulphide modified chelating resin for toxic metal adsorption from acid mine wastewater. Separation and Purification Technology. 2020. Vol. 251. ID 117407.

28. Małgorzata Szlachta, Raisa Neitola, Sirpa Peräniemi, Jouko Vepsäläinen. Effective separation of uranium from mine process effluents using chitosan as a recyclable natural adsorbent. Separation and Purification Technology. 2020. Vol. 253. ID 117493.
29. Tarantseva K. R., Fayustova Yu. A. Evaluation of the efficiency of wastewater purification from iron, copper and nickel ions with sorbent from water treatment waste. Ecology and Industry of Russia. 2022. No. 10. pp. 36–39.
30. Feng Xiao, Yanxia Cheng, Pengcheng Zhou. et al. Fabrication of novel carboxyl and amidoxime groups modified luffa fiber for highly efficient removal of uranium(VI) from uranium mine water. Journal of Environmental Chemical Engineering. 2021. Vol. 9, Iss. 4. ID 105681.
31. Hermassi M., Granados M., Valderrama C., Ayora C., Cortina J. L. Recovery of Rare Earth Elements from acidic mine waters by integration of a selective chelating ion-exchanger and a solvent impregnated resin. Journal
of Environmental Chemical Engineering. 2021. Vol. 9. Iss. 5. ID 105906.
32. Rybak L. V., Alekseev G. F., Burtsev S. V. et al. Worn-out tire сarbon-containing sorbents for quarry water treatment. Ugol. 2018. No. 7. pp. 62–67.
33. Batoeva A. A., Sizykh M. R., Munkoeva V. A., Tsybikova B. A. Solar irradiation prospects in cyanide-bearing wastewater decontamination. Mining informational and analytical bulletin. 2021. No. 7. pp. 53–69.
34. Budaev S. L., Batoeva A. A., Tsybikova B. A. et al. Photochemical degradation of thiocyanate by sulfate radical-based advanced oxidation process using UVС KrCl-excilamp. Journal of Environmental Chemical Engineering. 2021. Vol. 9, Iss. 4. ID 105584.
35. Griboff J., Wunderlin D. A., Monferran M. V. Phytofiltration of As3+, As5+, and Hg by the aquatic macrophyte Potamogeton pusillus L, and its potential use in the treatment of wastewater. International Journal of Phytoremediation. 2018. Vol. 20, Iss. 9. pp. 914–921.
36. Wongchai Anupong, Khumchai Jutamas, Ruangwong Onuma. et al. Bioremediation competence of Aspergillus flavus DDN on pond water contaminated by mining activities. Chemosphere. 2022. Vol. 304. ID 135250.
37. Efaq Ali Noman, Adel Al-Gheethi, Mohammed Al-Sahar. et al. Challenges and opportunities in the application of bioinspired engineered nanomaterials for the recovery of metal ions from mining industry wastewater. Chemosphere. 2022. Vol. 308, Р.1. ID 136165.
38. José Ignacio Suárez, Marcelo Aybar, Iván Nancucheo. et al. Influence of operating conditions on sulfate reduction from real mining process water by membrane biofilm reactors. Chemosphere. 2020. Vol. 244. ID 125508.
39. Yun Liu, James Vaughan, Gordon Southam et al. Role of the substrate on Ni inhibition in biological sulfate reduction. Journal of Environmental Management. 2022. Vol. 316, ID 115216.
40. Dabir, A., Heidari, P., Ghorbani, H., Ebrahimi A. Cadmium and lead removal by new bacterial isolates from coal and aluminum mines. International Journal of Environmental Science and Technology. 2019. Vol. 16. pp. 8297–8304.
41. Beauclair Nguegang, Vhahangwele Masindi, Titus Alfred Msagati Makudali et al. Effective treatment of acid mine drainage using a combination of MgO-nanoparticles and a series of constructed wetlands planted with Vetiveria zizanioides: A hybrid and stepwise approach. Journal of Environmental Management. 2022. Vol. 310. ID 114751.
42. Varun Gupta, Josee Courtemanche, John Gunn, Nadia Mykytczuk. Shallow floating treatment wetland capable of sulfate reduction in acid mine drainage impacted waters in a northern climate. Journal of Environmental Management. 2020. Vol. 263. ID 110351.
43. Elham Nariyan, Christian Wolkersdorfer, Mika Sillanpää. Sulfate removal from acid mine water from the deepest active European mine by precipitation and various electrocoagulation configurations. Journal of Environmental Management. 2018. Vol. 227. pp. 162–171.
44. Cumali Yılmaz, Fuat Güzel. Performance of wild plants-derived biochar in the remediation of water contaminated with lead: Sorption optimization, kinetics, equilibrium, thermodynamics and reusability studies. International Journal of Phytoremediation. 2022. Vol. 24, Iss. 2. pp. 177–186.
45. İlknur Şentürk, Nur Sena Eyceyurt Divarcı, Mustafa Öztürk. Phytoremediation of nickel and chromium-containing industrial wastewaters by water lettuce (Pistia stratiotes). International Journal of Phytoremediation. 2022. Vol. 25, Iss. 5. pp. 550–561.
46. Padmaja Galgali, Supriya Palimkar, Arindam Adhikari. et al. Remediation of potentially toxic elements-containing wastewaters using water hyacinth – A review. International Journal of Phytoremediation. 2023. Vol. 25, Iss. 2, pp. 172–186.
47. Blanco-Vieites M., Suárez-Montes D., Hernández Battez A., Rodríguez E. Enhancement of Arthrospira sp. culturing for sulfate removal and mining wastewater bioremediation. International Journal of Phytoremediation. 2022. Vol. 25, Iss. 9. pp. 1116–1126.
48. Madhumita Das, Bramhanand P. S., Laxminarayana K. Performance and efficiency services for the removal of hexavalent chromium from water by common macrophytes. International Journal of Phytoremediation. 2021. Vol. 23, Iss. 10. pp. 1095–1103.
49. Priyanka Saha, Omkar Shinde, Supriya Sarkar. Phytoremediation of industrial mines wastewater using water hyacinth. International Journal of Phytoremediation. 2016. Vol. 19, Iss. 1. pp. 87–96.
50. Romanova T. E., Shuvaeva O. V., Belchenko L. А. Phytoextraction of trace elements by water hyacinth in contaminated area of gold mine tailing. International Journal of Phytoremediation. 2015. Vol. 18, Iss. 2. pp. 190–194.
51. Muhammad Bilal Shakoor, Shafaqat Ali, Muhammad Rizwan. et al. A review of biochar-based sorbents for separation of heavy metals from water. International Journal of Phytoremediation. 2019. Vol. 22, Iss. 2. pp. 111–126.
52. Fatih Deniz, Elif Tezel Ersanli. A renewable biosorbent material for green decontamination of heavy metal pollution from aquatic medium: A case study on manganese removal. International Journal of Phytoremediation. 2021. Vol. 23, Iss. 3. 231–237.
53. Vhahangwele Matodzi, Malebogo Andrew Legodi, Nikita Tawanda Tavengwa. Effectiveness of wetlands to phytoremediate zinc, lead and chromium. International Journal of Phytoremediation. 2021. Vol. 23, Iss. 8. pp. 857–865.

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