500 rub
Journal Electromagnetic Waves and Electronic Systems №1 for 2026 г.
Article in number:
Quantum parameters of the fine structure constant of the elements in the Mendeleev table
Type of article: scientific article
DOI: https://doi.org/10.18127/j15604128-202601-06
UDC: 621.396
Keywords: Fine structure constant quantum numbers of the Mendeleev table energy-technological processes
Authors:

L.V. Lysenko1, D.M. Akhmelkin2, A.K. Gorbunov3, V.K. Shatalov4, N.A. Tikhonov5, A.E. Platonov6, K.S. Janaev7

1,2 JSC "Experimental Design Bureau of Microelectronics" (Kaluga, Russia)

3–7 Kaluga branch of Bauman Moscow State Technical University (National Research University) (Kaluga, Russia)

4 vkshatalov@yandex.ru

Abstract:

The assessment of numerical values of the fine structure constant for each element of the Mendeleev table allows us to expand the list of epistemological tools of physics. The dimensionless complexes of the fine structure constant are a consequence of the formalization of the quantum structures of the elements of the Mendeleev table. Theoretical and experimental data on energy-technological processes of critical structural materials allow us to justify this approach in this field of science and technology. To develop a methodology for formalizing the parameters of numerical values of the fine structure constant for each element of the Mendeleev table based on the equations of quantum parameters of energy-technological processes. The dimensionless numerical values of the fine structure constant for each element of the Mendeleev table have been evaluated in terms of the Planck constant, the charge in the element's atom, the electric constant, and the speed of light.

Pages: 76-85
For citation

Lysenko L.V., Akhmelkin D.M., Gorbunov A.K., Shatalov V.K., Tikhonov N.A., Platonov A.E., Janaev K.S. Quantum parameters of the fine structure constant of the elements in the Mendeleev table. Electromagnetic waves and electronic systems. 2026. V. 31. № 1. P. 76−85. DOI: https://doi.org/10.18127/j15604128-202601-06 (in Russian)

References
  1. Lysenko L.V., Akhmelkin D.M., Shatalov V.K., Tikhonov N.A., Platonov A.E., Petrunin A.E. Dimensionless quantum parameters of the elements of the periodic table. Electromagnetic waves and electronic systems. 2025. V. 30. № 2. P. 43−50. DOI 10.18127/j15604128-202502-05. (in Russian)
  2. Akhmelkin M.A., Lysenko L.V. Creative Russian microelectronics. Kaluga: Manuscript. 2020. 68 p. (in Russian)
  3. Lysenko L.V., Shatalov V.K. Energy technology approach to the physical meaning of the fundamental fine structure constant. Science Intensive Technologies. 2023. V. 24. № 6. P. 22−28. DOI 10.18127/j19998465-202306-02. (in Russian)
  4. Lysenko L.V., Shatalov V.K. Energy technological interpretation of Maxwell equations. Electromagnetic waves and electronic systems. 2023. V. 28. № 2. P. 64−72. DOI 10.18127/j15604128-202302-08. (in Russian)
  5. Lysenko L.V., Korzhavyi A.P., Romanov A.V., Shatalov V.K., Chelenko A.V. Application of the energy technology approach to the interpretation of the nature of the magnetic wave and light. Electromagnetic waves and electronic systems. 2021. V. 26. № 3. P. 48−53. DOI 10.18127/j15604128-202103-06. (in Russian)
  6. Leonov V.P., Gorynin I.V., Kudryavtsev A.S., Ivanova L.A., Travin V.V., Lysenko L.V. Titanium alloys in steam turbine construction. Inorganic Materials: Applied Research. 2015. V. 6. № 6. P. 580–590. DOI 10.1134/S2075113315060076.
  7. Shatalov V.K., Korzhavy A.P., Lysenko L.V., Mikhaylov V.I., Blatov A.A. Increasing the strength of the deposits of titanium alloys using rods process by microarc oxidation. Welding International. 2017. V. 31. № 12. P. 964–968. DOI 10.1080/09507116.2017.1369055.
  8. Lysenko L.V., Akhmelkin D.M., Shatalov V.K., Gorbunov A.K. Energy-technological quantum parameters of silicon in electronics. Science Intensive Technologies. 2024. V. 25. № 5. P. 16−23. DOI 10.18127/j19998465-202405-02. (in Russian)
  9. Shatalov V.K., Lysenko L.V., Govorun T.A., Shtokal A.O. Technological Procedure for the Formation of an Oxide Layer on the Surfaces of Structures Made of Titanium Alloys. Protection of Metals and Physical Chemistry of Surfaces. 2019. V. 55. № 7. P. 1352–1356. DOI 10.1134/S2070205119070153.
  10. Lysenko L.V., Shatalov V.K., Gorbunov A.K. A quantum approach to the periodic table. Electromagnetic waves and electronic systems. 2024. V. 29. № 2. P. 14−21. DOI 10.18127/j15604128-202402-02. (in Russian)
  11. Casado J. Connecting Quantum and Cosmic Scales by a Decreasing-Light Speed Model. [Electronic resource] – Access mode: https://arxiv.org/pdf/astro-ph/0404130, date of reference 10.10.2026.
  12. Vikhman E. Berkeley course of physics. V. 4. Quantum physics. Moscow: Nauka. 1986. 392 p. (in Russian)
  13. Elementary particles. Transl. from English by M.K. Polivanova; ed. by B.V. Medvedev. Moscow: Nauka. 1965. 140 p. (in Russian)
  14. Planck Collaboration. Planck 2015 results: XIII. Cosmological parameters. [Electronic resource] – Access mode: https://arxiv.org/pdf/1502.01589, date of reference 10.10.2026.
  15. Lysenko L.V. Gnoseological foundations of energy technology processes: textbook. Moscow: AI Pi Ar Media. 2023. 75 p. (in Russian)
  16. Lysenko L.V. Theoretical foundations of design assessments of energy-technological processes. Moscow: Energoatomizdat. 1997. 66 p. (in Russian)
  17. Korzhavy A.P., Lysenko L.V., Shatalov V.K., Gorbunov A.K., Lysenko A.L. The gravitational pull in power technological interpretation. Science Intensive Technologies. 2015. V. 16. 9. P. 5660. (in Russian)
  18. Lysenko L.V., Shatalov V.K., Gorbunov A.K., Lysenko A.L., Ovcharenko I.N. Power technological interpretation of the organic law of dynamics. Science Intensive Technologies. 2014. V. 15. . 8. P. 5558. (in Russian)
  19. Lysenko S.L., Blatov A.A. Derivation of Coulomb's law for magnetic charges. Electromagnetic waves and electronic systems. 2016. V. 21. 5. P. 1923. (in Russian)
  20. Shatalov V.K., Korzhavyi A.P., Lysenko L.V. Mechanical Properties and Structure of Titanium-Alloy Overlays Alloyed With Oxygen from the Oxide Layer of Filler Rods. Metal Science and Heat Treatment. 2020. V. 62. № 7-8. P. 524–528. DOI 10.1007/s11041-020-00596-z.
  21. Gnedenkov S.V., Gordienko P.S., Lysenko L.V., Sinebryukhov S.L., Khrisanova O.A., Skorobogatova T.M., Minaev A.I., Blinnikov O.V. Effect of coatings formed on titanium by microarc oxidation on the intensity of the salt deposition process. Fizika i khimiya obrabotki materialov. 1997. № 2. P. 65–69.
  22. Amelicheva K.A., Gorbunov A.K., Lysenko A.L., Lysenko L.V., Shatalov V.K. Theoretical approaches to teleportation processes. Science Intensive Technologies. 2017. V. 18. 10. P. 1723. (in Russian)
  23. Lysenko L.V., Shatalov V.K. Theory of the diffusion-kinetic model in microarc oxidation. Corrosion: materials, protection. 2006. 10. P. 4043. (in Russian)
  24. Travin V.V., Lysenko L.V. A study of the temperature fields in a bearing bush with anisotropic carbon-reinforced plastic. Questions of materials science. 2001. 2(26). P. 124129. (in Russian)
  25. Shatalov V.K., Korzhavy A.P., Lysenko L.V., Mikhailov V.I., Blatov A.A. Increasing the strength of titanium alloy surfacings with rods treated with microarc oxidation. Welding production. 2017. 3. P. 813. (in Russian)
  26. Shatalov V.K., Lysenko L.V., Shtokal A.O. Plasma-electrolytic treatment of developed surfaces from titanium during the formation of protective coatings on them. Electromagnetic waves and electronic systems. 2019. V. 24. № 6. P. 32–37. DOI 10.18127/j15604128-201905-05. (in Russian)
Date of receipt: 19.11.2025
Approved after review: 03.12.2025
Accepted for publication: 22.12.2025