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Home / Faculty of Engineering and Physics / Department “Physical Materials Science” / Narivskyi Alexei Eduardovych

Narivskyi Alexei Eduardovych

Narivskyi Alexei Eduardovych

Position

professor

Academic degree

Ph.D.

Academic title

docent

Education

1983 Zaporizhzhia Institute of Mechanical Engineering, specialty “Equipment and technology of welding production” Graduated with honors Theses: From 2004 to 2008, he studied at Zaporizhia National Technical University, majoring in “Materials Science”, which he graduated in 2008, and in 2009 he successfully defended his PhD thesis “Corrosion behavior of structural materials for plate heat exchangers in circulating waters” in the specialty “Chemical resistance of materials and corrosion protection”. In 2015, he defended his doctoral thesis “Regularities and mechanisms of local corrosion of corrosion-resistant steels and austenitic alloys for capacitive and heat exchange equipment” in the specialty “Chemical resistance of materials and corrosion protection”

Subjects taught

Introduction to the specialty Heating devices

Main languages ​​of communication

Ukrainian, English, French B2

Participation in the work of councils and state structures:

  • Member of the Scientific and Technical Council of the Ministry of Energy of Ukraine (nuclear safety section)

  • Member of the scientific and technical council on problems of corrosion and anti-corrosion protection at the Presidium of the National Academy of Sciences of Ukraine

Accounts of a scientist

Scientific interests:

  • corrosion

  • nuclear energy

Основні наукові роботи

  1. Narivs'kyi O.E. Corrosion fracture of plate-like heat exchanger // Materials Science, 2005, 1 (41), pp. 122-128. DOI: https://doi.org/10.1007/s11003-005-0140-8. Percentile 72.

  2. Narivs'kyi O.E. Micromechanism of corrosion fracture of the plates of heat exchangers // Materials Science, 2007, 43(1), p. 124-132. DOI: https://doi.org/10.1007/s11003-007-0014-3. Percentile 69.

  3. Narivs'kyi O.E. Micromechanism of corrosion fracture of the plates of heat exchangers // Materials Science, 2007, 43(1), p. 124-132. DOI: https://doi.org/10.1007/s11003-007-0014-3. Percentile 69.

  4. Narivs'kyi O.E., Belikov S.B. Pitting resistance of 06KhN28MDT alloy in chloride-containing media // Materials Science, 2008, 44 (4), p. 573-580. DOI: https://doi.org/10.1007/s11003-009-9107-5. Percentile 66.

  5. Narivs'kyi O. E. Corrosion Fracture of Platelike Heat Exchangers // Fiz.-Khim. Mekh. Mater., 2005, 41 (1), pp. 104-108. DOI: https://doi.org/10.1007/s11003-005-0140-8.

  6. Narivskiy A.E. Assessment of AISI321 steel resistance to local corrosion in chloride-containing media // Materials: corrosion, protection, 2008, 8, pp.1-7.

  7. Belikov S.B., Narivskyi O.E., Oleksandrov O.G. Production technology of a separator for separating recirculating hydrogen-containing gas from hydrotreating products // New materials and technologies in metallurgy and mechanical engineering, 2009, No. 2, p. 60-64

  8. Belikov S.B., Narivskyi O.E. Resistance of AISI 321 steel to intergranular corrosion depending on its structure and mechanical properties // New materials and technologies in metallurgy and mechanical engineering, 2010, No. 2, pp. 21-25.

  9. Mishchenko V.G., Snizhnoi G.V., and Narivs'kyy O.Eh. Magnetometric Investigations of Corrosion Behavior of AISI 304 Steel in Chloride-Containing Environment // Metallofizika i noveishie tehnologii, 2011, 33 (6), pp. 769-774. https://mfint.imp.kiev.ua/ru/toc/v33/i06.html. WOS:000296945600005.

  10. Mishchenko V.G., Snizhnoi G.V., and Narivs'kyy O.Eh. Magnetometric Investigations of Corrosion Behavior of AISI 304 Steel in Chloride-Containing Environment // Metallofizika i noveishie tehnologii, 2011, 33 (6), pp. 769-774. https://mfint.imp.kiev.ua/ru/toc/v33/i06.html. WOS:000296945600005.

  11. Narivskyi O.E., Belikov S.B. Resistance of AISI321 and 12Х18Н10Т steels to intergranular corrosion depending on their chemical composition // New materials and technologies in metallurgy and mechanical engineering, 2012, No. 2, pp. 20-24.

  12. Narivskyi O.E. Patterns and mechanisms of corrosion dissolution of AISI321 steel in model circulating waters // Bulletin of the Eastern Ukrainian National University named after Volodymyr Dahl, 2013, 202 (3), pp. 97-108.

  13. Narivskyi O.E. Patterns and mechanisms of corrosion dissolution of AISI321 steel in a weakly acidic chloride-containing solution // Bulletin of the Azov State Technical University, technical science series, 2013, issue 26, p. 97-108.

  14. Narivsky A.E., Yar-Mukhamedova G.Sh. Influence of chemical composition and structural components of alloy 06KhN28MDT on its corrosion losses in neutral chloride-containing solutions // Kompleksnoe ispolzovanie Miniralnogo Syra, 2013, 286(1), pp.82-98.

  15. Narivsky A.E., Yar-Mukhamedova G.Sh. Patterns and mechanisms of corrosion dissolution of Cr, Ni and Fe from the alloy 06KhN28MDT in chloride-containing solution // Kompleksnoe ispolzovanie Miniralnogo Syra, 2013, 286 (3), p.60-69.

  16. Narivskyi O.E. Effect of chemical composition and structural heterogeneity on corrosion losses of Cr, Ni and Fe from 06KHN28MDT alloy in model circulating water // Scientific Notes. Interuniversity Collection of Lutsk Technical University, 2013, 41, p. 177-183.

  17. Narivskyi O.E., Belikov S.B. Patterns and mechanisms of corrosion dissolution of AISI304 steel under sediment in model circulating waters // New materials and technologies in metallurgy and mechanical engineering, 2013, No. 1, p. 27-31.

  18. Narivskyi O.E. The influence of chemical elements and structural heterogeneity of AISI321 steel on the corrosion dissolution of Cr, Ni and Fe in chloride-containing solutions // Scientific Bulletin of the National Forestry University of Ukraine, 2014, 24(2), p.164-172.

  19. Narivsky A.E., Yar-Mukhamedova G.Sh. Pitting resistance of AISI321 steel in low-mineralized chloride-containing media depending on the ferrite phase content // Kompleksnoe ispolzovanie Miniralnogo Syra, 2014, 288 (1), pp. 58-67.

  20. Narivskyi O.E. Corrosion behavior of 06KHN28MDT alloy in model circulating water under sediment // Scientific bulletin of the National Forestry University of Ukraine, 2014, 24(1), p.162-171.

  21. Narivskyi O.E. The influence of alloying elements and the structure of AISI321 steel on the features of selective dissolution of metals in pitting on its surface // New materials and technologies in machine building, 2015, No. 2, p. 17-22.

  22. Narivsky A.E., Yar-Mukhamedova G.Sh. Influence of alloying elements and structural heterogeneity of AISI321 steel on the selective dissolution of metals from pitting // Bulletin of Al-Farabi Kazakh National University. Physical Series, 2016, 56(1), pp. 86-97.

  23. Narivskyi O.E., Belikov S.B., Markova N.V. Characteristic features of the selective dissolution of the 06XH28MDT alloy in a highly oxidizing solution of nitric acid // Scientific Bulletin of the National Forestry University of Ukraine, 2016, 26 (6), p.233-240.

  24. Narivskiy A., Yar-Mukhamedova G., Temirgalyeva E., Yar-Mukhamedov Y. Corrosion loss of alloy 06KhN28MDT in chloride containing commercial waters // International Multidisciplinary Scientific GeoConference Surveying Geology and Mining Ecology Management, SGEM, 2016, 1, pp.63-70.

  25. Narivskyi O.E. Peculiarities of selective dissolution of metals in metastable and stable pittings of 06XH28MDT alloy in model circulating waters // New materials and technologies in metallurgy and mechanical engineering, 2017, 2, p.46-53.

  26. Narivskyi O.E., Markova N.V. The effect of characteristic features of selective dissolution of the 06XH28MDT alloy on its durability to MCC in a highly oxidizing environment // Scientific notes. Lutsk National University, 2017, 57, c.144-151.

  27. Narivskiy A., Atchibaev R., Muradov A., Mukashev K., Yar-Muchamedov Y. Investigation of electrochemical properties in chloride-containing commercial waters // International Multidisciplinary Scientific GeoConference Surveying Geology and Mining Ecology Management, SGEM, 2018, 18 (6.1), pp. 267-274. DOI: 10.5593/sgem2018/6.1/S24.036.

  28. Korniienko O.V., Subbotin S.O., Narivskyi O.E. Neural network modeling of critical temperatures for steel pitting // Technical facilities of information registration and processing, 2019, 21 (1), pp. 57-67. https://doi.org/10.35681/1560-9189.2019.1.1.179699.

  29. Narivskyi O.E., Belikov S.B., Yar-Mukhamedova G.Sh. Mechanisms of corrosion destruction in pitting of 06XH28MDT alloy in model circulating waters // New materials and technologies in metallurgy and mechanical engineering, 2019, No. 1, p.53-60. DOI: 10.15588/1607-6885-2018-1-8

  30. Narivskyi A.E., Subbotin S.A., Belikov S.B., Yar-Mukhamedova G.Sh., Atchibaev R.A. Pitting resistance of AISI321 steel in chloride-containing media depending on its chemical composition and structural heterogeneity // Bulletin of Al-Farabi Kazakh National University, 2019, 131, pp. 240-250.

  31. Narivskyi O.E., Subbotin S.O. Belikov S.B., Yar-Mukhamedova G. Sh. Influence of circulation water's parameters, chemical composition and structural heterogeneity of AISI304 steel on its pitting resistance // Kompleksnoe ispolzovanie Miniralnogo Syra, 2019, 309(2), pp. 24-33. https://doi.org/10.31643/2019/6445.13. WOS: 000613024200004.

  32. Narivskyi O.E., Belikov S.B. The influence of the chemical composition and structural heterogeneity of the 06XH28MDT alloy on its pitting mechanisms in circulating waters // New materials and technologies in metallurgy and mechanical engineering, 2019, N2, c.6-13. DOI: https://doi.org/10.15588/1607-6885-2019-2-1

  33. Narivskyi O.E., Belikov S.B. The influence of the chemical composition and structural heterogeneity of the 06XH28MDT alloy on its pitting mechanisms in circulating waters // New materials and technologies in metallurgy and mechanical engineering, 2019, N2, c.6-13. DOI: https://doi.org/10.15588/1607-6885-2019-2-1

  34. Khoma M.S., Narivskyy O.E., Vinar V.A., Ratska N.B., Mardorevych R.C., Korniy S.A., Vasyliv Ch.B., Chuсhman M.R. Development of new constructive elements of gas cooling in atomic and thermal power plants with improved corrosion-mechanical resistance // Science and Innovation, 2021, 17(6), pp. 50-60. https://doi.org/10.15407/scine17.06.050. WOS:000736976100005.

  35. Leoshchenko S.D., Subbotin S.A., Narivs`kyy O.E. Implementation of the indicator system in modeling of complex technical systems // Radio Electronics, Computer Science, Control, 2021, No. 1, pp. 117-126. DOI: https://doi.org/10.15588/1607-3274-2021-1-12.

  36. Narivskyi O.E., Subbotin S.A., Pulina T.V. and Khoma M.S. Assessment and Prediction of the Pitting Resistance of Plate-Like Heat Exchangers Made of AISI304 Steel and Operating in Circulating Waters // Materials Science, 2022, 58, pp. 41–46. DOI: https://doi.org/10.1007/s11003-022-00628-4. Percentile 58.

  37. Narivs'kyi O., Atchibayev R., Kemelzhanova A., Yar-Mukhamedova G., Snizhnoi G., Subbotin S., Beisebayeva A. Mathematical Modeling of the Corrosion Behavior of Austenitic Steels in Chloride-Containing Media During the Operation of Plate-Like Heat Exchangers // Eurasian Chemico-Technological Journal, 2022, 24(4), pp. 295-302. DOI: https://doi.org/10.18321/ectj1473

  38. Narivskyi O.E., Subbotin S.O., Pulina T.V., Leoshchenko S.O., Khoma M.S., Ratska N.B. Modeling of pitting of heat exchangers made of 18/10 type steel in circulating waters// Materials Science, 2023, 58(5), pp.1-7. DOI: https://doi.org/ 10.1007/s11003-023-00725-y. Percentile 22.

  39. Narivs'kyi O.E., Subbotin S.O., Pulina T.V. Corrosion behavior of austenitic steels in chloride-containing media during the operation of plate-like heat exchangers // Physical Sciences And Technology, 2023, 10 (3-4), pp. 48-56. DOI: https://doi.org/10.26577/phst.2023.v10.i2.06

  40. Narivskyi O.E., Snizhnoi G.V., Pulina T.V., Snizhnoi V.L., Solidor N.A. The influence of the specific magnetic susceptibility of AISI 304 and 08X18N10 steels on their limit potentials in chloride-containing environments // Physico-chemical mechanics of materials, 2023, 6, p. 22-31.

Contacts

Address:

69063, Ukraine, Zaporizhzhia, 64 Zhukovsky St

Classroom:

158

e-mail:

amz309@ukr.net
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