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SECONDARY RAW MATERIAL PROCESSING
Название Muscovite and ceramic pegmatite dumps in the Arctic regions of Karelia as a potential raw material for industrial use
DOI 10.17580/or.2021.05.06
Автор Myasnikova O. V., Bubnova T. P.
Информация об авторе

Institute of Geology of the Karelian Research Centre, Russian Academy of Sciences (Petrozavodsk, Russia):

Myasnikova O. V., Researcher, Candidate of Engineering Sciences, okmyasn@krc.karelia.ru
Bubnova T. P., Researcher, bubnova@krc.karelia.ru

Реферат

mining enterprises in the Loukhsky region of the Republic of Karelia, rated as one of the Arctic regions of the Russian Federation. The purpose of this study was to establish the rock composition of the dumps and identify the possibility of their use in various industries. It has been found that pegmatite dumps are mainly represented by quartz, microcline and plagioclase pegmatite, micas (muscovite, intergrowths of muscovite with biotite), overburden and host rocks (gneisses, gneiss granites, amphibolites, and gabbro). Quartz raw materials may be used to produce silicon carbide, as well as in the glass industry, in fine ceramics, welding consumables, silica refractory products, and investment casting. Plagioclase concentrate may be used to obtain low-temperature porcelain and coarse crushed plagioclase for the glass industry. Fine and crushed muscovite is used as a filler in the rubber industry, for coating arc welding electrodes, in the manufacture of paints and varnishes, plastics, paper, titaniummica pigments, and composite materials. The host rocks may be used to produce crushed stone. After proper additional processing, lump ceramic raw materials from the dumps of ceramic pegmatites may be used to obtain fine and construction-grade ceramics and in the glass industry. Pegmatite processing waste is suitable for the manufacture of decorative crushed stone and crushed stone for filling secondary roads. Further processing and subsequent use of pegmatite dumps allows organizing environmentally friendly mining operations and preserving the resource potential of the subsoil.
The research was conducted under the financial support from the federal budget for the fulfillment of the state assignment set for the Karelian Research Center of the Russian Academy of Sciences (121040600172-1).

Ключевые слова Pegmatite deposits, mining waste, quartz, feldspar, muscovite, overburden and host rocks, crushed stone
Библиографический список

1. Waste disposal — problems, solutions. Analytical review. Мoscow, 2015. 27 p. URL: https://extech.ru/files/anr_2015/anr_5.pdf (accessed: 20.03.2021).
2. Rational use of secondary mineral resources in the conditions of greening and introduction of the best available technologies: monograph / Ed. Larichkin F. D., Knysh V. A. Apatity: KSC RAS, 2019. 254 p.
3. Zubkov A. A., Vorobyev A. E., Shulenina Z. M. The concept of resolving the mineral and raw material problems and the natural environment protection. Marksheyderiya i Nedropolzovanie. 2009. No. 4. pp. 23–32.
4. Yoshida K., Okuoka K., Tanikawa H. Anthropogenic disturbance by domestic extraction of construction minerals in Japan. Journal of Industrial Ecology. 2017. Vol. 22. pp. 145–154.
5. Murguía D. I., Bringezu S., Schaldach R. Global direct pressures on biodiversity by large-scale metal mining: Spatial distribution and implications for conservation. Journal of Environmental Management. 2016. Vol. 180. pp. 409–420.
6. Fernandes G. W., Ribeiro S. P. Deadly conflicts: Mining, people, and conservation. Perspectives in Ecology and Conservation. 2017. Vol. 15. pp. 141–144.
7. Lèbre E., Corder G. D., Golev A. Sustainable practices in the management of mining waste: A focus on the mineral resource. Minerals Engineering. 2017. Vol. 107. pp. 34–42.
8. Terrones-Saeta J. M., Suárez-Macías J., del Río F. J. L., Corpas-Iglesias F. A. Study of copper leaching from mining waste in acidic media, at ambient temperature and atmospheric pressure. Minerals. 2020.Vol. 10. DOI: 10.3390/min10100873.
9. Amarab H., Benzaazoua M., Edahbi M., Villeneuve M., Joly M. A., Elghali A. Reprocessing feasibility of polymetallic waste rock for cleaner and sustainable mining. Journal of Geochemical Exploration. 2021. Vol. 220. DOI: 10.1016/j.gexplo.2020.106683.
10. Ozhogina E. G., Kotova O. V., Yakushina O. A., Zhukova V. E. On the possibility of secondary use of mining wastes. Geoekologiya. Inzhenernaya Geologiya, Gidrogeologiya, Geokriologiya. 2020. No. 2. pp. 58–63.
11. Ozhogina E. G., Yakushina O. A., Kozlov A. P. Mineralogical peculiarities and recycling prospects of nickelcontaining metallurgical slags. Obogashchenie Rud. 2017. No. 3. pp. 49–56. DOI: 10.17580/or.2017.03.08.
12. Kotova O., Ozhogina E. Applied mineralogy of mining industrial wastes. Proc. of 14th International congress for applied mineralogy (ICAM 2019). Springer, Cham. pp. 103–106.
13. Buravchuk N. I., Guryanova O. V. The use of man-made materials in the manufacture of non-metallic building materials. Izvestiya Vysshikh Uchebnykh Zavedeniy. Severo-Kavkazskiy Region. Tekhnicheskie Nauki. 2015. No. 1. pp. 111–117.
14. Khudyakova L. I., Timofeeva S. S. Practical use of non-metallic raw materials of copper-nickel deposits. Yug Rossii: Ekologiya, Razvitie. 2018. Vol. 13, No. 4. pp. 157–165.
15. Alushkin I. V., Yushina T. I., Rassulov V. A., Voronkin A. V. Investigation possibility use radiometric methods of technogenic dumps quartz-feldspar mine Hetolambina. Gorny Informatsionno–analiticheskiy Byulleten'. 2013. No. 7. pp. 66–72.
16. Arkhipov A. V., Reshetnyak S. P. Technogenic deposits. Development and formation. Apatity: RSC RAS, 2017. 175 p.
17. Butov I. I., Orlova I. G. Mining complex of Russia: the inevitability of ecological modernization. Ekologicheskiy Vestnik Rossii. 2019. No. 2. pp. 41–47.
18. Shishkov A. Yu. Emerging prospects of mining waste utilization in the Karelian-Kola region. Trudy Karelskogo Nauchnogo Tsentra RAN. 2020. No. 2. pp. 90–97.
19. Warell L. Mineral deposits safeguarding and land use planning—The importance of creating shared value. Resources. 2021. Vol. 10. DOI: 10.3390/resources10040033.
20. Production volumes in the mining complex of Karelia have increased. The official Internet portal of the Republic of Karelia. URL: https://gov.karelia.ru/news/18-12-2019-v-gornopromyshlennom-komplekse-karelii-vyrosli-obemyproizvodstva-/?special_version=Y (accessed: 20.04.2021).
21. Bubnova T. P., Skamnitskaya L. S., Ilyina V. P. Feldspar raw material in the Republic of Karelia and its technological assessment. Trudy Karelskogo Nauchnogo Tsentra RAN. 2020. No. 6. pp. 58–74.
22. Decree of the President of the Russian Federation of June 27, 2017 No. 287 «On amendments to the Decree of the President of the Russian Federation of May 2, 2014 No. 296 «On the land territories of the Arctic zone of the Russian Federation». URL: http://publication.pravo.gov.ru/Document/View/0001201706270043 (accessed: 15.02.2021).
23. Atlas of the Karelian ASSR / Ed. Peikhwasser V. N. Moscow: Main Directorate of Geodesy and Cartography under the Council of Ministers of the USSR, 1989. 40 p.
24. Shchiptsov V. V., Ivashchenko V. I. Mineral resource potential of the Arctic regions of the Republic of Karelia. Trudy Karelskogo Nauchnogo Tsentra RAN. 2018. No. 2. pp. 3–33.
25. Mineral resource base of the Republic of Karelia. Bk. 2. Non-metallic minerals. Petrozavodsk: Karelia, 2006. 355 p.
26. Skropyshev A. V. On the classification of industrial pegmatites of northern Karelia and the direction of prospecting and exploration for mica. Zapiski Gornogo Instituta. 1953. Vol. 28. pp. 141–148.
27. Kulikov V. S., Svetov S. A., Slabunov A .I., Kulikova V. V., Polin A. K., Golubev A. I., Gor'kovets V. Ya., Ivaschenko V. I., Gogolev M. A. Geological map of southeastern Fennoscandia at a scale of 1: 750,000: new approaches to compilation. Trudy Karelskogo Nauchnogo Tsentra RAN. 2017. No. 2. pp. 3–41.
28. Biryulev G. I., Gonyukh V. M., Bobrikova E. V., Kornilov A. V. Mineral raw materials. Quartz sand. Directory. Moscow: Geoinformmark, 1999. 36 p.
29. Skamnitskaya L. S., Bubnova T. P., Rakov L. T., Dubinchuk V. T. Structural-mineralogical and technological features of quartz of mica pegmatites of Chupino-Loukhsky district of Karelia. The role of technological mineralogy in obtaining the final products of mineral processing: collection of articles of the X Russian seminar on technological mineralogy. 2016. pp. 87–94.
30. Chertov А. N., Gorbunova E. V., Skamnitskaya L. S., Bubnova Т. P. Possibilities of quartz-feldspathic mineral material processing by means of photometric sorting by the example of the North Karelian deposits. Obogashchenie Rud. 2015. No. 4. pp. 54–59. DOI: 10.17580/or.2015.04.10.
31. Shishelova T. I., Zhitov V. G. Modern condition of the mica sphere. Problems and prospects. Uspekhi Sovremennogo Estestvoznaniya. 2018. No. 3. pp. 133–139.

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