AbstractAbout AuthorsReferences
In this paper mechanisms of construction composite evolution when it’s using under varied environmental conditions from the point of view of technogenic matasomatosis are studied. The term «technogenic matasomatosis in construction material science» is formed and developed in framework of scientific field «geonics» and «geomimetics». The functional system of metasomatic transformation of construction composite is presented using metasomatic column as an example. The importance of thermodynamic analysis for energy potential of material surface as a basis for metasomatic transformations is shown. The main theoretical problems of technogenic matasomatosis in construction material science are observed. Solution of them will be a base for design of composites with self-sealing properties and composites those are able to adapt to environmental exposure. Development of this research field is oriented on improving of comfortability of the Homo Sapiens in the system «human – material – life environment».
V.S. LESOVIK1, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.)
E.V. FOMINA1, Candidate of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.)
A.M. AYZENSHTADT2, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.)
E.V. FOMINA1, Candidate of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.)
A.M. AYZENSHTADT2, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.)
1 Belgorod State Technological University named after V.G. Shukhov (46, Kostyukova Street, Belgorod, 308012, Russian Federation)
2 Northern (Arctic) Federal University of M.V. Lomonosov (17, emb. Northern Dvina, Arkhangelsk, 163002, Russian Federation)
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3. Vedernikova A.S. A membrane form of a metasomatoz in silicon minerals – primary source of life on Earth. Problems of geology and development of a subsoil: works VII of the International symposium of a name of the academician M.A. Usov devoted to the 400 anniversary of Tomsk. Tomsk: TPU. 2004. pp. 751–754. (In Russian).
4. Gorokhova M.S. Paradoxes of a metasomatoz of vegetable and live substance and problem of biomineralogy. Mineralogiya tekhnogeneza. 2012. No. 3, pp. 190–201. (In Russian).
5. Pospelov G.L. Paradoxes, geological and physical essence and mechanisms of a metasomatoz [Paradoksy, geologo-fizicheskaya sushchnost’ i mekhanizmy metasomatoza]. Novosibirsk: Nauka.1973. 353 p.
6. Korzhinsky D.S. A sketch of metasomatic processes. The main problems in the doctrine about magmatogenny ore fields. Moscow: Academy of Sciences of the USSR publishing house. 1955, pp. 334–456. (In Russian).
7. Lesovik V.S. Geonika (geomimetika). Primery realizacii v stroitel’nom materialovedenii. [Geonickname (geomimmetics). Examples of realization in construction materials science]. Belgorod: BSTU. 2014. 206 p.
8. Lesovik V.S., Fomina E.V. Crystal-genetic aspects of a technogenic metasomatoz in construction materials science. Intellectual construction composites for green construction: The international scientific and practical conference devoted to the 70 anniversary of the honored worker of science of the Russian Federation, the corresponding member of RAACS, the Doctor of Engineering, prof. V.S. Lesovik. Belgorod: BGTU of V.G. Shukhov. 2016, pp. 151–156. (In Russian).
9. Bhanumathidas N., Kalidas N. Metabolism of cement chemistry. The Indian Concrete Journal. 2003. Vol. 77 (9), pp. 1304–1306.
10. Lesovik V.S. Genetic bases of energy saving in the industry of construction materials. Izvestiya vuzov. Stroitel’stvo. 1994. No. 7, 8, pp. 96–100. (In Russian).
11. Lesovik V.S. Geonika. Predmety i zadachi [Geonics. Subject and objectives]. Belgorod: BSTU. 2012. 100 p.
12. Lesovik V.S., Mospan A.V., Belentsov Yu.A. Silicate products on the granulated fillers for aseismic construction. Vestnik BGTU im. V.G. Shuhova. 2012. No. 4, pp. 62–65. (In Russian).
13. Lessowik W.S. 2015. Geonik. Geomimetik als grundlage für die synthese von intelligent bauverbundwerkstoffen. 19 Internationale baustofftagung ibausil. Weimar: Bauhaus-Universitat. рр. 183–189.
14. Zapivalov N.P., Gurieva S.M., Dakhnova M.V., Pankina R.G., Serdyuk Z.Ya. Communication of isotope composition of CO2 carbon and carbonates with collection properties of carbonate breeds. Doklady Akademii nauk SSSR. 1982. No. 2 (262), pp. 396–399. (In Russian).
15. Zapivalov N.P. Imposed metasomatoz: natural and technogenic nanoeffects. Problems of geology and development of a subsoil: works XVII of the International symposium of a name of the academician M.A. Usov of students and young scientists devoted to the 150 anniversary since the birth of the academician V.A. Obruchev and to the 130 anniversary of the academician M.A. Usov, founders of the Siberian mining-and-geological school. Tomsk: TPU. 2013, pp. 228–231. (In Russian).
16. Korzhinskiy D.S. Izbrannye trudy. Osnovy metasomatizma i metamagmatizma. [Chosen works. Bases of metasomatism and metamagmatism]. Moscow: Nauka. 1993. 239 p.
17. Korzhinsky D.S. Open systems with quite mobile components and the rule of phases. Izvestiya AN SSSR. Seriya geologiya. 1949. No. 2, pp. 3–14. (In Russian).
18. Shabalin L.I. Osnovy molekulyarno-kineticheskoj koncepcii rudo- i magmoobrazovaniya [Basics of the molecular-kinetic concept of ore and magma formation]. Novosibirsk: SNIIGGIMS. 2002. 204 p.
19. Chudnenko K.V. Termodinamicheskoe modelirovanie v geohimii: teoriya, algoritmy, programmnoe obespechenie, prilozheniya [Thermodynamic modeling in geochemistry: theory, algorithms, software, and applications]. Novosibirsk: GEO. 2010. 287 p.
20. Rakov L.T., Dubinchuk V.T., Skamnitskaya L.S., Nippers V.V. Mobile impurity in quartz of the Karelian-Kola region. Trudy Karel’skogo nauchnogo centra RAN. 2016. No. 10, pp. 100–110. (In Russian).
21. Zuev V.V., Pocelueva L.N., Goncharov Yu.D. Kristalloehnergetika kak osnova ocenki svojstv tverdotel’nyh materialov [Crystalloenergy as the basis for assessing the properties of solid materials]. Saint-Petersburg: 2006. 139 p.
22. Imre Biczok Concrete corrosion risk and concrete protection. Budapest: Akademiai Kiado. 1964. 548 p.
23. Andrеs E.I., Carlos M.L., Ignacio C. Chemo-mechanical analysis of concrete cracking and degradation due to external sulfate attack: A meso-scale model. Cement & Concrete Composites. 2012. Vol. 34, pp. 903–910.
24. Glass G.K. and Buenfeld N.R. The influence of chloride binding on the chloride induced corrosion risk in reinforced concrete. Corrosion Science. 2000. Vol. 42 (2), pp. 329–344.
25. Safarov K.B., Stepanova V.F. Regulation of reaction capacity of fillers and increasing sulfate resistance of concretes by combined use of low-calcium fly ash and high-active metakaolin. Stroitel’nye Materialy [Construction Materials]. 2016. No. 5, pp. 70–73. (In Russian).
26. Safarov K.B., Stepanova V.F., Falikman V.R. Effect of mechanical activated low-calcium fly ash on corrosion resistance of hydrotechnical concretes of the Rogun hydropower plant. Stroitel’nye Materialy [Construction Materials]. 2017. No. 10, pp. 20–25. (In Russian).
2. Lesovik V.S. Geonika (geomimetika). Primery vnedreniya v oblasti materialovedeniya. [Geonickname (geomimmetics). Implementation examples in construction material science]. Belgorod: BSTU. 2016. 287р.
3. Vedernikova A.S. A membrane form of a metasomatoz in silicon minerals – primary source of life on Earth. Problems of geology and development of a subsoil: works VII of the International symposium of a name of the academician M.A. Usov devoted to the 400 anniversary of Tomsk. Tomsk: TPU. 2004. pp. 751–754. (In Russian).
4. Gorokhova M.S. Paradoxes of a metasomatoz of vegetable and live substance and problem of biomineralogy. Mineralogiya tekhnogeneza. 2012. No. 3, pp. 190–201. (In Russian).
5. Pospelov G.L. Paradoxes, geological and physical essence and mechanisms of a metasomatoz [Paradoksy, geologo-fizicheskaya sushchnost’ i mekhanizmy metasomatoza]. Novosibirsk: Nauka.1973. 353 p.
6. Korzhinsky D.S. A sketch of metasomatic processes. The main problems in the doctrine about magmatogenny ore fields. Moscow: Academy of Sciences of the USSR publishing house. 1955, pp. 334–456. (In Russian).
7. Lesovik V.S. Geonika (geomimetika). Primery realizacii v stroitel’nom materialovedenii. [Geonickname (geomimmetics). Examples of realization in construction materials science]. Belgorod: BSTU. 2014. 206 p.
8. Lesovik V.S., Fomina E.V. Crystal-genetic aspects of a technogenic metasomatoz in construction materials science. Intellectual construction composites for green construction: The international scientific and practical conference devoted to the 70 anniversary of the honored worker of science of the Russian Federation, the corresponding member of RAACS, the Doctor of Engineering, prof. V.S. Lesovik. Belgorod: BGTU of V.G. Shukhov. 2016, pp. 151–156. (In Russian).
9. Bhanumathidas N., Kalidas N. Metabolism of cement chemistry. The Indian Concrete Journal. 2003. Vol. 77 (9), pp. 1304–1306.
10. Lesovik V.S. Genetic bases of energy saving in the industry of construction materials. Izvestiya vuzov. Stroitel’stvo. 1994. No. 7, 8, pp. 96–100. (In Russian).
11. Lesovik V.S. Geonika. Predmety i zadachi [Geonics. Subject and objectives]. Belgorod: BSTU. 2012. 100 p.
12. Lesovik V.S., Mospan A.V., Belentsov Yu.A. Silicate products on the granulated fillers for aseismic construction. Vestnik BGTU im. V.G. Shuhova. 2012. No. 4, pp. 62–65. (In Russian).
13. Lessowik W.S. 2015. Geonik. Geomimetik als grundlage für die synthese von intelligent bauverbundwerkstoffen. 19 Internationale baustofftagung ibausil. Weimar: Bauhaus-Universitat. рр. 183–189.
14. Zapivalov N.P., Gurieva S.M., Dakhnova M.V., Pankina R.G., Serdyuk Z.Ya. Communication of isotope composition of CO2 carbon and carbonates with collection properties of carbonate breeds. Doklady Akademii nauk SSSR. 1982. No. 2 (262), pp. 396–399. (In Russian).
15. Zapivalov N.P. Imposed metasomatoz: natural and technogenic nanoeffects. Problems of geology and development of a subsoil: works XVII of the International symposium of a name of the academician M.A. Usov of students and young scientists devoted to the 150 anniversary since the birth of the academician V.A. Obruchev and to the 130 anniversary of the academician M.A. Usov, founders of the Siberian mining-and-geological school. Tomsk: TPU. 2013, pp. 228–231. (In Russian).
16. Korzhinskiy D.S. Izbrannye trudy. Osnovy metasomatizma i metamagmatizma. [Chosen works. Bases of metasomatism and metamagmatism]. Moscow: Nauka. 1993. 239 p.
17. Korzhinsky D.S. Open systems with quite mobile components and the rule of phases. Izvestiya AN SSSR. Seriya geologiya. 1949. No. 2, pp. 3–14. (In Russian).
18. Shabalin L.I. Osnovy molekulyarno-kineticheskoj koncepcii rudo- i magmoobrazovaniya [Basics of the molecular-kinetic concept of ore and magma formation]. Novosibirsk: SNIIGGIMS. 2002. 204 p.
19. Chudnenko K.V. Termodinamicheskoe modelirovanie v geohimii: teoriya, algoritmy, programmnoe obespechenie, prilozheniya [Thermodynamic modeling in geochemistry: theory, algorithms, software, and applications]. Novosibirsk: GEO. 2010. 287 p.
20. Rakov L.T., Dubinchuk V.T., Skamnitskaya L.S., Nippers V.V. Mobile impurity in quartz of the Karelian-Kola region. Trudy Karel’skogo nauchnogo centra RAN. 2016. No. 10, pp. 100–110. (In Russian).
21. Zuev V.V., Pocelueva L.N., Goncharov Yu.D. Kristalloehnergetika kak osnova ocenki svojstv tverdotel’nyh materialov [Crystalloenergy as the basis for assessing the properties of solid materials]. Saint-Petersburg: 2006. 139 p.
22. Imre Biczok Concrete corrosion risk and concrete protection. Budapest: Akademiai Kiado. 1964. 548 p.
23. Andrеs E.I., Carlos M.L., Ignacio C. Chemo-mechanical analysis of concrete cracking and degradation due to external sulfate attack: A meso-scale model. Cement & Concrete Composites. 2012. Vol. 34, pp. 903–910.
24. Glass G.K. and Buenfeld N.R. The influence of chloride binding on the chloride induced corrosion risk in reinforced concrete. Corrosion Science. 2000. Vol. 42 (2), pp. 329–344.
25. Safarov K.B., Stepanova V.F. Regulation of reaction capacity of fillers and increasing sulfate resistance of concretes by combined use of low-calcium fly ash and high-active metakaolin. Stroitel’nye Materialy [Construction Materials]. 2016. No. 5, pp. 70–73. (In Russian).
26. Safarov K.B., Stepanova V.F., Falikman V.R. Effect of mechanical activated low-calcium fly ash on corrosion resistance of hydrotechnical concretes of the Rogun hydropower plant. Stroitel’nye Materialy [Construction Materials]. 2017. No. 10, pp. 20–25. (In Russian).
For citation: Lesovik V.S., Fomina E.V., Ayzenshtadt A.M. Some aspects of technogenic metasomatosis in construction material science. Stroitel’nye Materialy [Construction Materials]. 2019. No. 1–2, pp. 100–106. DOI: https://doi.org/10.31659/0585-430X-2019-767-1-2-100-106 (In Russian).