New opportunities of multifunctional materials

Silicate materials traditionally occupy an important place in materials science, despite the ever-changing demands. The improvement of materials requires the development of theory. The extensive experience accumulated by technical and experimental mineralogy does not always agree with traditional ideas and, sometimes, does not find an explanation in them at all. Such a situation arises in trying to describe the anomalously high kinetic parameters of diffusion and crystallization in glass and ceramics. The search for a solution to the problem leads to the use of the most general laws of natural science, the theory of oscillations and waves. Under the conditions of nonequilibrium crystallization in artificial silicate systems, the mechanism of spinodal decomposition is found, which is later confirmed in volcanic glasses of the Earth and Moon as well as in tektites. The proposed model of spatially closed dynamic structures takes into account the kinetics of phase transformations, when the formation of segregation products (molecular clusters) and bonds between them is of a resonant nature. As a result, a new class of multifunctional materials with an unusual combination of physical and chemical properties is created. Synthetic metasilicates masters about three dozen new technological applications in medicine (surgery, dentistry), household production, and aerospace equipment, materials science (modifying additives in ceramics, polyethylene, linoleum, asphalt), heatand wear-resistant lining, gold and slag pipelines. The economic efficiency of glass ceramics is shown on the example of the Federal Project The Northern Latitudinal Railway.

1. Manankov А.V. Segregation mechanism in silicate systems. DAN SSSR. 1979; 246 (4): 942–946. (In Russian)

2. Manankov A.V., Sharapov V.N. Kinetics of phase transitions in basic melts and magmas. Novosibirsk: Nauka. 1985. 199 p. (In Russian)

3. Loktyushin A.A., Manankov A.V. Spatially closed dynamic structures. Tomsk: TSU, 1996. 121 p. (In Russian)

4. Terletskiy Ya.P. Elektrodinamika. Moscow: Vysshaya shkola, 1990. 129 p. (In Russian)

5. Masterova M.A., Yantz Yu.G. The Umov-Poynting vector of dipole electric and dipole magnetic moments. Available: www.vestnik.adygnat.ru (In Russian)

6. Manankov А.V. The theory of formation and forecast of mineral deposits. Geosfemyye issledovaniya. 2019; (4): 83–94. (In Russian)

7. Manankov A.V., Gasanova E.R., Kharitnova N.V. Crystal-chemical bases for calculation of glassceramics monominerality. Neorganicheskie materialy. 2018; 54 (9): 984–992. (In Russian)

8. Manankov A.V., Gasanova E.R. Glass-ceramics from local raw materials for the production of innovative infrastructures with high technical and economic efficiency in the Far North conditions. Izvestiya Tomskogo politekhnicheskogo universiteta. Inzhiniring georesursov. 2018; 329 (11): 87–96. (In Russian)

9. Manankov A.V., Gasanova E.R., Bykova V.V. Physicochemical and technological aspects of glass-ceramics of a new class. Vestnik Voronezhskogo GUIT. 2018; 80 (1): 211–222. (In Russian)

10. Manankov A.V. Structural organization of innovative petrositalls from the local natural raw materials of the Polar Urals. Insights in Mining Science and Technology. 2020; 2 (1): 153–161. DOI: 10.19080/IМТ.2020.02.555577 (In Russian)

11. Kipriyanov N.A., Gorichev N.G. Electron-proton theory as fundamental basis for physicochemical process of leaching of oxide minerals in hydrometallurgy. Vestnik RUDN. Seriya: Inzhenernye issledovaniya. 2006; 1 (12): 101–109. (In Russian)

12. Kondrat'yev B.K., Turchin V.I. Combuned ion source. Pribory i tekhnika eksperimenta. 1994; (3): 106–111. (In Russian)

13. Turchin V.I., Rad'ko V.E. Diamond polishing device. Patent Russ. Fed. No. 2211760, 2003. (In Russian)

14. Shelli R. Jove. The Pribram-Bohm hypothesis a topology of consciousness. Cosmos and History. The Journal of Natural and Social Philosophy. 2016; 12 (2): 114–136.

15. Aspect A., Grangier P., Roger G. Experimental realization of Einstein-Podolsky-Rosen-Bohm gedankenexperiment – A new violation of bell inequalities. Physical Review Letters. 1982; 49 (2): 91–94.

16. Talbot M. The holographic universe. Moscow: Sofia, 2004. 368 p. (Russian translation)

17. Kozyrev N.A. Causal or asymmetric mechanics in linear approximation. Pulkovo, 1958. 41 p. (In Russian)

18. Kuz'min A.M. Periodic-rhythmic phenomena in mineralogy and geology. Tomsk: STT, 2019. 336,p. (In Russian)

19. Parun V.E., Grinyayev Yu.V., Danilov V.I, Zuyev L.V., et al. Structural levels of plastic deformation and fracture. Novosibirsk: Nauka, 1990. 254 p. (In Russian)

20. Popsulin S. Russian scientist from Harvard made a breakthrough in the quantum computer space. Izdamye о vysokikh tekhnologiyakh, 2012. (In Russian)

21. Korzhinskiy D.S. The theory of metasomatic zoning. Moscow: Nauka, 1982. 104 p. (In Russian)

22. Chepizhnyy K.I. New in mineralogy (theory of mineralogy). Leningrad: Nauka, 1988. 146 p. (In Russian)

23. Manankov A.V. Physicochemical foundations of nanostructural mineralogy in new material production. Vestnik of Tomsk State University of Architecture and Building. 2012; (2): 120–136. (In Russian)

24. Manankov A.V., Vladimirov V.M., Strakhov B.S. Mechanism for structure formation and nonequilibrium glass crystallization model (A review). Glass and Ceramics. 2015; (1): 3–10. DOI: 10.1007/s10717-015-9710-x

25. Trademark Certificate No. 92355 “SIKAM" is a new 19th class of artificial stones, building, non-metallic materials”,1990. (In Russian)

26. Manankov A.V., Goryukhin E.Ya., Loktyushin A.A. Wollastonite, pyroxene and other materials from industrial waste and non-deficient natural raw materials. Tomsk: TSU, 2002. 168 p. (In Russian)

27. Manankov A.V., Vladimirov V.M., Gasanova E.R. Method for preparing metasilicate glassceramic mixture. Patent Russ. Fed. No. 2687014, 2019. (In Russian)

28. Loktyushin A.A., Manankov A.V. Mineral structure in holographic model of substance. Struktura i evolyutsiya mineral'nogo mira. Syktyvkar, 1997. Pp. 35–37. (In Russian)

29. Manankov A.V., Vladimirov V.M. On the mechanism and thermodynamic modeling of metasilicate glass ceramics crystallization. Glass and Ceramics. 2016; (6): 3–7. DOI: 10.1007/s10717-016-9856-l

30. Shubina Yu.S., Strakhov B.S., Manankov A.V. Geodynamics of the Arctic shelf and methane emanation from gas hydrates. In: Proc. 9th All-Russ. Sci. Conf., Tomsk: TPU, 2016. Pp. 10–19. (In Russian)

31. Pavlushkin N.M. Fundamentals of glass-ceramic technology. Moscow: Stroyizdat, 1979. 340 p. (In Russian)

32. Vernadskii V.I. Scientific thought as a planetary phenomenon. Moscow: Nauka, 1991. 271 p. (In Russian)

33. Manankov A.V., Loktyushin A.A. Production method for porous vitrified block. Author's Certificate No. 1787965, 1993. (In Russian)

34. Manankov A.V., Karaush S.A. Production method and design of porous vitrified block. Patent Russ. Fed. No. 2525076, 2014. (In Russian)

35. Manankov A.V., Vladimirov V.M., Gasanova E.R. Production method for porous glass ceramics (options). Patent Russ. Fed. No. 2582152, 2015. (In Russian)