Low-energy self-organization of coherent structures in non-equilibrium crystallization
DOI:
https://doi.org/10.55287/22275398_2026_58_109Keywords:
metasilicates, sikam, petro-slag ceramics, mineral raw materials, autointerference, vibrational modes, kinetics, nonequilibrium processes, spinodal decomposition, isomorphismAbstract
Relevance. Various attempts to explain the crystallization of viscous silicate melts under varying degrees of stationarity are driven by the growing need for new materials to support technological progress. It is currently accepted that the entire diversity of solid materials is encompassed by several phase states with crystal structures obeying Fedorov space groups. The unit cell possesses parameters, translating which allows for the construction of a fairly realistic description of crystals, determined by the Gibbs phase. Experimental mineralogy data often diverge from traditional concepts, particularly when describing anomalous diffusion kinetics and phase transformations in crystallizing glasses and glass-ceramics.
The goal of this work is to develop a method for describing crystals that takes into account forces of at least equal magnitude, somehow related to internal properties and vibrational modes. To this end, we used our holographic model of matter, in which these interactions can form their own coherent structures with their own types of resonant lattices.
The following problems were solved: structural ordering factors determined by spatiotemporal coherence were identified; a resonance model of dynamic structures was substantiated that adequately describes the kinetics of low-energy phase transformations; and a classification of materials by the nature of bonds and types of coherence was developed.
Methods. The model of a generalized approach to assessing multi-scale processes and phenomena is based on the results of fundamental experimental research and their analysis, taking into account well-known concepts of electrodynamics and wave mechanics.
Results. For the first time, a model of spatially closed dynamic structures of real matter was developed, describing objects and interactions at the micro-, meso-, and macro-levels as a set of self-interference of a closed wave process. Interaction between regions of constructive interference occurs at the beat frequencies of the main wave process, generating a spatial lattice of the next hierarchical level.
References
1. Eitel V. Physical chemistry of silicates. Moscow: IL; 1968. 1055 p.guides.library.ualberta
2. Epelbaum M.V. Calculation of the temperature of the maximum rate of crystallization of glasses. Glass and Ceramics. 1958;(4):22–25.guides.library.ualberta DOI: https://doi.org/10.1007/BF00669631
3. Kirkpatrick R.J. Kinetics of crystal growth in the system CaMgSi2O6–CaAl2SiO6. American Journal of Science. 1974;274(3):215–242.guides.library.ualberta DOI: https://doi.org/10.2475/ajs.274.3.215
4. Manankov A.V., Loktyushin A.A. Dynamic model of crystallization. In: Proceedings of the II All-Russian Conference “Physicochemical Modeling in Geochemistry and Petrology on a Computer”. Irkutsk; 1988. p. 70.guides.library.ualberta
5. Boroznovskaya N.N., Lesnov F.P., Manankov A.V. On the influence of various forms of potassium manifestation on the luminescence of basic plagioclases. In: Proceedings of the V All-Union Symposium on the Problem of Isomorphism. Saint Petersburg: RMO; 1981. p. 44–47.guides.library.ualberta
6. Manankov A.V., Loktyushin A.A., Baev S.Yu. Dynamics of the structure of F-aggregate color centers in crystals. In: Proceedings of the VI All-Union Symposium on Isomorphism. Moscow: GEOKHI; 1988. p. 135.guides.library.ualberta
7. Manankov A.V., Loktyushin A.A., Baev S.Yu. Radiation sensitization of defects in crystals. In: Proceedings of the VI All-Union Symposium on Isomorphism. Moscow: GEOKHI; 1988. p. 136.guides.library.ualberta
8. Loktyushin A.A., Manankov A.V. Polarization translation of phase transitions and the dynamics of formation of alkaline-earth element metasilicates in viscous melts. Mineralogy, Geochemistry and Useful Minerals of Siberia. 1990;1:16–22.guides.library.ualberta
9. Sanina V.A., Golovenchits E.I. Polarization interactions and phase transitions in crystals with two interacting subsystems. Physics of the Solid State. 2000;42(5):905–909.guides.library.ualberta DOI: https://doi.org/10.1134/1.1131314
10. Manankov A.V. On the mechanism of liquation in silicate systems. Doklady Akademii Nauk SSSR. 1979;246(4):942–946.guides.library.ualberta
11. Romanov B.P., Manankov A.V., Golovko N.V. Study of solid solutions of the clinoenstatite–diopside system by dilatometry and electrical conductivity methods. Inorganic Materials. 1985;21(9):1539–1543.guides.library.ualberta
12. Manankov A.V., Sharapova V.N. Kinetics of phase transitions in basic melts and magmas. Novosibirsk: Nauka; 1985. 199 p.guides.library.ualberta
13. Manankov A.V., Yakovlev V.M. Unconventional building materials of the “sikam” class. Building Materials. 1995;(9):16–17.guides.library.ualberta
14. Loktyushin A.A., Manankov A.V. Spatially closed dynamic structures. Tomsk: Tomsk State University Publishing House; 1996. 121 p.guides.library.ualberta
15. Terletsky Ya.P. Electrodynamics. Moscow: Vysshaya Shkola; 1990. 129 p.guides.library.ualberta
16. Masterova M.A., Yants Yu.G. Umov–Poynting vector of dipole electric and dipole magnetic moments. Available from: http://www.vestnik.adygnat.ruguides.library.ualberta
17. Zvezdin A.K., Matveev V.M., Mukhin A.A., Popov A.I. Rare earth ions in magnetically ordered crystals. Moscow: Nauka; 1985. 294 p.guides.library.ualberta
18. Manankov A.V. Astromineralogy – a new complex science for solving raw material and environmental problems of the biosphere. Petrology of Igneous and Metamorphic Complexes. 2016;8:204–211.guides.library.ualberta
19. Manankov A.V. Native and rare earth metals on the Earth, the Moon, in tektites and meteorites. Geophysical Processes and the Biosphere. 2018;17(2):111–130.guides.library.ualberta
20. Manankov A.V. On the theory of formation and forecast of mineral deposits. Geospheric Studies. 2019;(4):83–94.guides.library.ualberta DOI: https://doi.org/10.17223/25421379/13/8
21. Manankov A.V., Gasanova E.R., Kharitonova N.V. Crystallochemical foundations for calculating the monomineralism of glass-ceramics. Inorganic Materials. 2018;54(9):984–992.guides.library.ualberta DOI: https://doi.org/10.1134/S0020168518090078
22. 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 extreme conditions of the Far North. Bulletin of Tomsk Polytechnic University. Geo Assets Engineering. 2018;329(11):87–96.guides.library.ualberta
23. Manankov A.V., Gasanova E.R., Bykova V.V. Physicochemical and technological aspects of the development of a new glass-ceramic class. Bulletin of the Voronezh State University of Engineering and Technology. 2018;80(1):211–222.guides.library.ualberta DOI: https://doi.org/10.20914/2310-1202-2018-1-211-222
24. Manankov A.V., Goryukhin E.Ya., Loktyushin A.A. Wollastonite, pyroxene and other materials from industrial waste and abundant natural raw materials. Tomsk: Tomsk State University Publishing House; 2002. 168 p.guides.library.ualberta
25. Kipriyanov Kh.A., Gorichev N.G. Electron–proton theory as a fundamental basis of the physicochemical process of oxide mineral leaching in hydrometallurgy. Bulletin of RUDN University. Series: Engineering Researches. 2006;1(12):101–109.guides.library.ualberta
26. Kondratyev B.K., Turchin V.I. Combined ion source. Pribory i Tekhnika Eksperimenta. 1994;(3):106–111.guides.library.ualberta
27. Turchin V.I., Radko V.E. Device for processing diamonds. Patent RF No. 2211760. IPC B28D 5/00, B44C 1/22, C30B 31/00, C30B 33/00. Application No. 2001114961/03; filed 31 May 2001; published 10 September 2003.guides.library.ualberta
28. Manankov A.V. Structural organization of innovative petrosals from the local natural raw materials of the Polar Urals. Insights in Mining Science and Technology. 2020;2(1):153–161. doi:10.19080/IMT.2020.02.555577.guides.library.ualberta DOI: https://doi.org/10.19080/IMST.2020.02.555577
29. Shelli R.J. Jove. The Pribram–Bohm hypothesis: a topology of consciousness II. Cosmos and History: The Journal of Natural and Social Philosophy. 2016;12(2):114–136.guides.library.ualberta
30. Aspect A., Grangier P., Roger G. Experimental realization of Einstein–Podolsky–Rosen–Bohm Gedanken experiment: a new violation of Bell inequalities. Physical Review Letters. 1982;49(2):91–94.guides.library.ualberta DOI: https://doi.org/10.1103/PhysRevLett.49.91
31. Talbot M. The holographic universe. Moscow: Sofia Publishing House; 2004. 368 p. (In Russian, transl. from English).guides.library.ualberta
32. Kozyrev N.A. Causal or asymmetric mechanics in the linear approximation. Pulkovo; 1958. 41 p.guides.library.ualberta
33. Kuzmin A.M. Periodic–rhythmic phenomena in mineralogy and geology. Tomsk: STT Publishing House; 2019. 336 p.guides.library.ualberta
34. Panin V.E., Grinzev Yu.V., Danilov V.I., Zuev L.V., et al. Structural levels of plastic deformation and fracture. Novosibirsk: Nauka; 1990. 254 p.guides.library.ualberta
35. Popsulin S. Russian scientist from Harvard made a breakthrough in the space of a quantum computer. High Technology Publication. 6 July 2012.guides.library.ualberta
36. Korzhinsky D.S. Theory of metasomatic zoning. Moscow: Nauka; 1982. 104 p.guides.library.ualberta
37. Chepizhny K.I. New in mineralogy (theory of mineralogy). Leningrad: Nauka; 1988. 146 p.guides.library.ualberta
38. Manankov A.V. Physicochemical foundations of nanostructured mineralogy in obtaining modern materials. Bulletin of Tomsk State University of Architecture and Civil Engineering. 2012;(2):120–130. doi:10.21455/GPB2018/2-7/.guides.library.ualberta
39. Certificate No. 92355 for the trademark “SIKAM” – new class 19 stones – artificial, building and structural non-metallic building materials. Priority 7 February 1990.guides.library.ualberta
40. Manankov A.V., Vladimirov V.M., Gasanova E.R. Method for preparing metasilicate glass-ceramic batch. Patent RF No. 2687014. IPC C03B 1/00. Application No. 2018116526; filed 3 May 2018; published 5 June 2019. 10 p. Bulletin No. 13.guides.library.ualberta
41. Loktyushin A.A., Manankov A.V. Mineral structure in a holographic model of substance. In: Structure and Evolution of the Mineral World. Syktyvkar; 1997. p. 35–37.guides.library.ualberta
42. 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/s10717-016-9856-1.guides.library.ualberta
43. Manankov A.V., Loktyushin A.A. Method for producing a porous vitrified block. Author’s certificate No. 1737965. Filed 14 August 1989; published 15 January 1993. Bulletin No. 2.guides.library.ualberta
44. Manankov A.V., Karaush S.A. Method and device for producing a porous vitrified block. Patent RF No. 2525076. IPC C03B 19/08, C03C 11/00. Application No. 2013127553/03; filed 17 June 2013; published 10 August 2014. 17 p. Bulletin No. 22.guides.library.ualberta
45. Manankov A.V. Method for manufacturing porous glass ceramics (variants). Patent RF No. 2582152. IPC C03B 19/08. Application No. 2015115361/03; filed 23 April 2015; published 20 April 2016. 10 p. Bulletin No. 11.guides.library.ualberta
46. Shubina Yu.S., Strakhov B.S., Manankov A.V. Geodynamics of the Arctic shelf and methane emission from gas hydrates. In: Proceedings of the IX All-Russian Scientific Conference with International Participation Named after Prof. M.K. Korovina. Tomsk: TPU; 2016. p. 10–19.guides.library.ualberta
47. Manankov A.V. University science in solving the country’s transport problems. In: Proceedings of the International Scientific Conference “Design, Construction, and Operation of Cement-Concrete Roads: International Experience and Russian Practice”; Moscow; 24–25 September 2020. p. 56–58. (In Russian).guides.library.ualberta
48. Manankov A.V., Bykov N.E. Priority scientific ideas for the northern latitudinal passage project and their technological development. In: Proceedings of the International Scientific Conference “Design, Construction, and Operation of Cement-Concrete Roads: International Experience and Russian Practice”; Moscow; 24–25 September 2020. p. 59–60. (In Russian).guides.library.ualberta
49. Pavlushkin N.M. Basics of glass-ceramic technology. Moscow: Stroyizdat; 1979. 340 p.guides.library.ualberta
50. Vernadsky V.I. Scientific thought as a planetary phenomenon. Moscow: Nauka; 1991. 271 p.guides.library.ualberta
