Rudenkov Aleksandr Sergeevich

Publications in Math-Net.Ru

1. Technological methods for controlling the structure and improving the mechanical properties of composite carbon coatings
   
   PFMT, 2025, no. 4(65),  7–13
2. Influence of heat treatment on the structure and mechanical properties of carbon coatings doped with zirconium and silicon
   
   PFMT, 2025, no. 3(64),  73–83
3. Influence of conditions and mode of formation of a sublayer based on ethyl cellulose and sulfuric acid on the structure of carbon coatings
   
   PFMT, 2025, no. 2(63),  35–43
4. Structure, mechanical properties of gradient nanocomposite copper-carbon coatings
   
   PFMT, 2025, no. 1(62),  43–50
5. Morphology and phase composition of carbon coatings formed on the surface of two-layer system based on ethyl cellulose and sulfuric acid
   
   PFMT, 2024, no. 4(61),  30–39
6. Influence of deposition conditions on the structure and mechanical properties of a-C coatings
   
   PFMT, 2024, no. 4(61),  7–12
7. Influence of heat treatment on the structure and mechanical properties of carbon coatings doped with zirconium and silicon
   
   PFMT, 2024, no. 2(59),  48–56
8. Molecular structure and anti-fungicidal properties of coatings based on clotrimazole and polymers formed from the active gas phase
   
   PFMT, 2024, no. 1(58),  50–56
9. Structure and mechanical properties of a-C coatings deposited from pulse carbon plasma on a ni heated sublayer
   
   PFMT, 2024, no. 1(58),  36–43
10. Synthesis and sorption properties of coatings based on hydroxyethyl cellulose intercalated from the gas phase with antibacterial compounds
    
    PFMT, 2023, no. 4(57),  53–59
11. Structure and mechanical properties of carbon coatings doped with zirconium and silicon
    
    PFMT, 2023, no. 4(57),  42–47
12. Effect of heat treatment on the morphology and structure of nanocomposite coatings based on starch and copper acetate
    
    PFMT, 2023, no. 1(54),  54–59
13. Influence of laser assistance on the processes of volatile products dispersion generation of composite targets based on polyethylene and their reactivity
    
    PFMT, 2022, no. 4(53),  64–72
14. Morphology and structure of nanocomposite polymer coatings containing lead formate
    
    PFMT, 2022, no. 4(53),  46–52
15. Features of the kinetics of polymers electron-beam dispersion under laser assisted conditions
    
    PFMT, 2022, no. 3(52),  61–66
16. Structure and mechanical properties of silicon-carbon coatings alloyed with chromium
    
    PFMT, 2022, no. 2(51),  52–57
17. Morphology and phase composition of nanostructured carbon coatings, formed on the sublayer based on polytetrafluoroethylene and lead formate
    
    PFMT, 2021, no. 4(49),  38–44
18. Morphology and phase composition of silicon-doped titanium carbon coatings
    
    PFMT, 2021, no. 3(48),  37–41
19. Influence of formation modes on morphology and phase composition of carbon coatings reinforced with multilayer carbon nanotubes
    
    PFMT, 2021, no. 2(47),  51–56
20. Structure and properties of a-C films containing metals and products of their interaction with nitrogen, carbon
    
    PFMT, 2021, no. 1(46),  24–30
21. Electron beam synthesis, structure and properties of single-component and magnesium doped zinc oxide coatings
    
    PFMT, 2020, no. 4(45),  81–87
22. Influence of ion-plasma nitrogen on the structure of composite coatings based on cellulose and carbon nanotubes
    
    PFMT, 2020, no. 4(45),  62–67
23. Features of the formation of coatings of metal oxides from the active gas phase under conditions of electron-initiated endothermic processes
    
    PFMT, 2020, no. 3(44),  50–54
24. Formation of composite coatings by electron beam dispersion of a mixture of iron, aluminum and PTFE in the conditions of exothermal interaction
    
    PFMT, 2020, no. 3(44),  30–34
25. Formation of structured coatings based on carbon and polyacrylamide, influence of thermal treatment on their phase composition and morphology
    
    PFMT, 2020, no. 2(43),  23–27
26. Boron-carbon coatings: methods of deposition, structure features and mechanical properties
    
    PFMT, 2019, no. 3(40),  7–12
27. Bioactive multilayer coatings that initiate bone growth: structure and properties
    
    PFMT, 2019, no. 2(39),  28–35
28. Molecular structure of single-layer and bi-layer coatings, which are perspective when used in osteosynthesis processes
    
    PFMT, 2019, no. 2(39),  21–27
29. Carbon nanotubes: classification, features of synthesis, research methods and applications
    
    PFMT, 2019, no. 2(39),  7–14
30. Phase composition and structure of multilayer nanosized metal-carbon coatings
    
    PFMT, 2018, no. 2(35),  34–37
31. Mechanical properties of carbon coatings, doped by carbide-forming metals
    
    PFMT, 2017, no. 4(33),  25–29
32. Influence of molecular nitrogen on optical properties of coatings based on refractory oxides
    
    PFMT, 2017, no. 3(32),  32–35
33. Influence of carbide-forming metals nature on the phase composition and structure of alloyed carbon coatings
    
    PFMT, 2017, no. 2(31),  24–30
34. Influence of ion nitriding on the phase composition, structure and properties of carbon coatings
    
    PFMT, 2016, no. 1(26),  37–41
35. Influence of metal concentration on the phase composition, structure and properties of carbon-metal coating
    
    PFMT, 2015, no. 3(24),  26–32
36. Size effect in the bilayer coatings of titanium-carbon. 2. The dependence of structure and properties on the thickness of carbon layer
    
    PFMT, 2014, no. 1(18),  16–20
37. Size effect in the bilayer coatings of titanium-carbon. 1. The influence of thickness of titanium interlayer on the structure and properties of carbon layer
    
    PFMT, 2013, no. 4(17),  38–42
38. Morphology and optical properties of multilayer refractory oxide coatings
    
    PFMT, 2013, no. 4(17),  21–27
39. Morphology and mechanical properties of carbon coatings obtained from plazma of combined pulse cathode-arc discharge
    
    PFMT, 2012, no. 3(12),  33–36
40. The morphology of the carbon based composition coatings processed by nitrogen ions
    
    PFMT, 2010, no. 3(4),  31–34