The relevance of research is due to the efficiency of development of minerals in the Arctic, which is largely determined by the transport and production infrastructure. Harsh climatic conditions of the Far North with a predominance of permafrost rocks (PR) significantly affect the economy and ecology of the territory, for which the cost of construction materials and structures are now reaches 70% of the cost of oil and gas. Mastering Yamal, yield on the shelves of the Arctic seas requires the creation of innovative technology breakthrough of oil and gas, including the construction of artificial islands and underwater constructions offshore. Such technologies are possible in the presence of modern building materials and structures that have many times greater strength, durability, durability, acid resistance and other functional parameters of the widest range for industrial, transport and civil construction. Glass-ceramic, as evidenced by the results of the analysis of scientific, technical and patent data are promising materials in the field of innovation in aviation, rocket and space technology, as well as other industries that require metal-substituting, lining and more sophisticated materials of construction with an unusual combination of properties : high mechanical, abrasive resistance, high dielectric properties and chemical resistance. The article presents the results of the creation of petrositalls of the new “Sikams” class (SCS), beginning with the method for calculating and estimating the composition of the charge, based on the principles of structural crystal chemistry, taking into account the revealed scales of isovalent and heterovalent isomorphism under conditions of directed crystallization. The method provides a high crystallization rate, achieving the required degree of structural and chemical homogeneity and best physico-chemical properties of the material, wherein a crystalline phase to form solid solution of pyroxene. The technological process is simplified and energy consumption is reduced. Object of research - the mineralogical and chemical composition of the charge, particularly glass immiscibility source types and nucleation mechanisms chain metasilicates polymorphs, their relationship to glass and kinetics saturation nanostructure.

petrositalls, metasilicates, sikam, monominerality, crystallochemical approach, stoichiometric coefficients, rocks of the Polar Urals, pile-trestle road structure, transport, commercial civil infrastructure

1. Sarkisov PD, Orlova LA, Popovich NV, Schegoleva NE et al. Thecurrentstateofthematter in the field of technology and production of glass-based aluminosilicate systems. Glass formation, crystallization and shaping in the production of strontium-anorthite and celstann steel satellites. Vse materialy [All materials] 2011. no. 8. pp. 1–19. (in Russian)

2. Zhunina LA, Kuzmenkov MI, Yaglov VN Piroksenovye sitally [Pyroxene Sital] Minsk, Publishing House of the Belarusian State University, 1974. 224 p. (in Russian)

3. Pavlushkin N.M. Osnovy tekhnologii [Fundamentals of technology of steel] Moscoww, Stroiizdat, 1979. 359 p. (in Russian)

4. Strnad Z. Steklokristallicheskie [Glasscrystalline material] Moscow: Stroiizdat, 1988. 256 p. (in Russian)

5. Artamonova M.V. Khimicheskaya tekhnologiya [Chemical technology of glass and glassware] Moscow, Stroiizdat, 1983. 432 p. (in Russian)

6. L?csei B. Molten Silicates and their Properties. Budapest, Academia Kiado, 1970. 135 p.

7. Manankov A.V. Physicochemical foundations of nanostructured mineralogy in obtaining modern materials. Vestnik TGASU [Proceedings of TSASU] 2012, no. 2. pp. 120–136 (in Russian)

8. Manankov AV, Bychkov DA, Strakhov BS, Yakovlev VM et al. Mineralogical and geochemical and experimental studies of the synthesis of petrositals. Mineralogiya, geokhimiya I poleznye iskopaemye [Collection "Mineralogy, geochemistry and minerals of Asia] 2012. pp. 10–18. (in Russian)

9. Bychkov DA, Manankov AV, Strakhov BS Mineralogical and petro-geochemical studies of the mountain raw material of the Polar Urals for the production of petrositals. Rossiya v Arktike [Materials of the All-Russian Youth Conference "Russia in the Arctic"] 2012. pp. 42–43. (in Russian)

10. Gasanova E.R, Manankov A.V. To the solution of off-road problems in the extraction of minerals in special conditions. UNTK-2017 [Materials of the 63rd University Scientific and Technical Conference of Students and Young Scientists (CNTK2017)] 2017. pp. 64–66. (in Russian)

11. Gasanova ER, Manankov A.V. Petrositall building structures for oil and gas production in special Arctic conditions. Zdorovaya okruzhayushchaya sreda [Materials of the first Ryazan International Environmental Forum "Healthy Environment – the Basis for Regional Security"] 2017. pp. 124–136. (in Russian)

12. Manankov AV, Karaush S.A. Development of a highly profitable technology for the production of porous vitrified blocks. Nauchno-innovatsionnaya deyatel’nost’ TGASU [Mater. proc. "Scientific and innovative activity of the Tomsk State. architect-builds. University in 2014»] 2015. pp. 126–127 (in Russian)

13. Rumi M. Kh., Nurmatov Sh. R., Mansurova E.P., Zufarov M.A. et al. Materials for boiler pipes surface protection. Glass and ceramic. 2017. no. 5. pp. 29–33.

14. Schindler M., Berti D., Hochella M.F. Previously unknown mineral-nanomineral relationships with important environmental consequences: The case of chromium release from dissolving silicate minerals. American Mineralogist. 2017. no. 102 (10). pp. 2142-2145. doi: 10.2138/am-2017-6170.

15. Manankov A.V., Vladimirov V.M., Strakhov B.S. Mechanism for structure formation and non-equilibrium glass crystallisation model (a review). Glass and ceramic. 2015. no. 1. pp. 3–10. doi: 10.1007/s10717–015–9710x.

16. Manankov A.V., Vladimirov V.M. On the mechanism and thermodynamic modeling of metasilicateglassceramics crystallization. Glass and ceramic. 2016. no. 6. pp. 3–7. doi: 10.1007/s10717–016–9856–1

17. Dir W.A. et al. Porodoobrazuyushchie mineraly [Pore-forming minerals] Moscow, Mir, 1966. 236 p. (in Russian)

18. Mandelbrot B.B. The fractal geometry of nature. New York, W.H. Freeman and Company, 1982. 464 p.

19. Pinsker G.Z. On an important property of short-range order in glasses. Fizika I khimiya stekla [Physics and Chemistry of Glass] 1979. pp. 509–516. (in Russian)

20. Vigouroux H., Fargin E., Fargues A., Garrec BL et al. Crystallization and second harmonic generation of lithium niobium silicate glass ceramics. Journal of the American Ceramic Society. 2011. vol. 94. no. 7. pp. 2080–2086. doi: 10.1111 / j. 1551–2916.2011.04416.x

21. Romanov BM, Manankov AV, Sazonov AM About phase and structural relations in the system of enstatite-diopside at atmospheric pressure . Geologiya I geofizika [Geology and geophysics] 1981. no. 10. pp. 67–76. (in Russian)

22. Manankov AV, Vladimirov VM, Strakhov B.S. High-strength petrositall structures for work in special Arctic conditions. Vestnik TGU [Journal of the TSU Bulletin] 2014. no. 385. pp. 223-232 (in Russian)

23. Loctyushin A.A., Manankov A.V. Mineral structure in holographic model of substance. Structure And Evolution of the Material World. 1997. pp. 35–37. (in Russian)

24. Medvedev E.F., Min'ko N.I. Silicate glasses permeability to hydrogen. Glass and ceramic. 2017. no. 1. pp. 3–6.

25. Min’ko N.I., Dobrinskaya O.A., Gridyakin K.N., Bulgakov A.S. Systematic approach to secondary products implementation in glass-making. Glass and ceramic. 2017. no. 5. pp. 3–6.

26. Stookey J.D. Catalyzed crystallization of glass in theory and practices. Glasstechn. 1959. 32 p.

27. Barbieri L., Ferrari A.M., Lancellotti I., Leonelli C. Crystallization of (Na2O–MgO) – CaO–Al2O3SiO2 Glassy Systems Formulated from Waste Products. Journal of the American Ceramic Society. 2000. vol. 83. no. 10. pp. 2515–2520.

28. Vigouroux H., Fargin E., Fargues A., Garrec B.L. et al. Crystallization and second harmonic generation of lithium niobium silicate glass ceramics. Journal of the American Ceramic Society. 2011. vol. 94. no 7. pp. 2080-2086. doi: 10.1111/j.1551-2916.2011.04416.x

29. Golodenko B.A., Golodenko A.B. Methods of quantum chemistry and nanotechnology as applied to the study of the energy states of amorphous tetrahedral structures. Vestnik VGUIT [Proceedings of the Voronezh State University of Engineering Technologies]. 2013. no. 1. pp. 78–83. (in Russian)