Рубцов Николай Михайлович

Публикации в базе данных Math-Net.Ru

1. Thermal ignition of a stoichiometric mixture of hydrogen and oxygen over nanoporous Ni, Co and Fe surfaces near the second ignition limit
   
   Mendeleev Commun., 36:2 (2026),  238–241
2. Features of dilute methane–oxygen flame front propagation towards combustible gas flow created by the fan
   
   Mendeleev Commun., 34:4 (2024),  576–578
3. Features of the interaction of the combustion front of methane–air mixtures with hollow cylindrical and conical obstacles at low pressures
   
   Mendeleev Commun., 34:2 (2024),  288–290
4. Features of ignition of mixtures of hydrogen with hydrocarbons (C₂, C₃ and C₅) over rhodium and palladium at pressures of 1–2 atm
   
   Mendeleev Commun., 34:1 (2024),  137–139
5. Ignition limits of hydrogen–methane–air mixtures over metallic Rh at a pressure of 1–2 atm
   
   Mendeleev Commun., 33:4 (2023),  574–576
6. Modes of interaction of counterflow flames in diluted methane–oxygen mixtures in a closed reactor
   
   Mendeleev Commun., 33:3 (2023),  433–435
7. Suppression of laminar flames of natural gas–oxygen mixtures with complex obstacles
   
   Mendeleev Commun., 33:2 (2023),  279–281
8. Influence of noble metals on thermoacoustic oscillations and boundaries of the region of negative temperature coefficient during combustion of n-pentane – air mixtures
   
   Mendeleev Commun., 32:5 (2022),  693–696
9. Surface modes of catalytic ignition of flammable gases over noble metals
   
   Mendeleev Commun., 32:4 (2022),  564–566
10. The features of ignition of hydrogen–methane and hydrogen–isobutene mixtures with oxygen over Rh and Pd at low pressures
    
    Mendeleev Commun., 32:3 (2022),  405–407
11. Исследование пассивации компактных образцов из пирофорных нанопорошков железа при их взаимодействии с воздухом
    
    Физика горения и взрыва, 57:3 (2021),  79–87
12. К 125-летию со дня рождения лауреата Нобелевской премии академика Николая Николаевича Семенова. Цепной механизм воздействия добавок дихлордифторметана на горение водорода и метана в кислороде и воздухе
    
    ЖТФ, 91:6 (2021),  895–903
13. Interaction dynamics between compacted pyrophoric nickel nanopowders and air
    
    Mendeleev Commun., 31:4 (2021),  567–569
14. The phenomenon of negative temperature coefficient in palladium-initiated combustion of hydrogen–propane–air mixtures
    
    Mendeleev Commun., 31:2 (2021),  274–276
15. Interaction between laminar flames of natural gas–oxygen mixtures and planar obstacles with asymmetrical openings
    
    Mendeleev Commun., 31:1 (2021),  132–134
16. Interaction of compact samples made of pyrophoric iron nanopowders with air
    
    Mendeleev Commun., 30:3 (2020),  380–382
17. Ignition of hydrogen–oxygen and stoichiometric hydrogen–methane–oxygen mixtures on hot wires at low pressures
    
    Mendeleev Commun., 30:2 (2020),  241–243
18. Catalytic activity of Pt and Pd in gaseous reactions of H₂ and CH₄ oxidation at low pressures
    
    Mendeleev Commun., 30:1 (2020),  121–123
19. Ignition of hydrogen–methane–air mixtures over Pd foil at atmospheric pressure
    
    Mendeleev Commun., 29:4 (2019),  469–471
20. Synthesis of tungsten nanopowders and modes of their combustion and passivation
    
    Mendeleev Commun., 29:3 (2019),  355–357
21. Penetration of the laminar flames of natural gas–oxygen mixtures through conical obstacles
    
    Mendeleev Commun., 29:1 (2019),  108–110
22. The modes of combustion of copper nanopowders
    
    Mendeleev Commun., 28:4 (2018),  447–449
23. The features of hydrogen ignition over Pt and Pd foils at low pressures
    
    Mendeleev Commun., 28:2 (2018),  216–218
24. Penetration of methane–oxygen flames through flat obstacles with several openings
    
    Mendeleev Commun., 28:1 (2018),  99–101
25. Combustion and passivation of nickel nanoparticles
    
    Mendeleev Commun., 27:6 (2017),  631–633
26. Passivation of iron nanoparticles at subzero temperatures
    
    Mendeleev Commun., 27:5 (2017),  482–484
27. Interaction of chemical processes over Pt wire and reactive flows of flame penetration through obstacles in the presence of iron nanopowder
    
    Mendeleev Commun., 27:4 (2017),  387–389
28. Ignition of hydrogen–air mixtures over Pt at atmospheric pressure
    
    Mendeleev Commun., 27:3 (2017),  307–309
29. Gas dynamics and kinetics of the penetration of methane–oxygen flames through complex obstacles, as studied by 3D spectroscopy and high-speed cinematography
    
    Mendeleev Commun., 27:2 (2017),  192–194
30. Relative contribution of gas dynamic and chemical factors to flame penetration through small openings in a closed cylindrical reactor
    
    Mendeleev Commun., 27:1 (2017),  101–103
31. Synthesis and characterization of passivated iron nanoparticles
    
    Mendeleev Commun., 26:6 (2016),  549–551
32. Temporal characteristics of ignition and combustion of iron nanopowders in the air
    
    Mendeleev Commun., 26:5 (2016),  452–454
33. Cellular combustion and delay periods of ignition of a nearly stoichiometric H₂–air mixture over a platinum surface
    
    Mendeleev Commun., 26:2 (2016),  160–162
34. Interaction of the laminar flames of natural gas–oxygen mixtures with planar obstacles, diffusers and confusers
    
    Mendeleev Commun., 26:1 (2016),  61–63
35. Взаимодействие ламинарных пламен метано-воздушных смесей с мелкоячеистыми плоскими и сферическими препятствиями в замкнутом цилиндрическом реакторе при инициировании искровым разрядом
    
    ХФМ, 17:2 (2015),  183–191
36. Establishment of features of unstable flame propagation using 3D optical spectroscopy and color speed cinematography
    
    Mendeleev Commun., 25:6 (2015),  482–484
37. Penetration of methane–oxygen flames through spherical and planar obstacles in a closed cylindrical reactor
    
    Mendeleev Commun., 25:4 (2015),  304–306
38. Dependence of burning velocity on the sample size in the nonactivated and mechanically activated Ni + Al systems
    
    Mendeleev Commun., 25:1 (2015),  67–69
39. Non-steady Propagation of single and Counter Hydrogen and Methane Flames in Initially Motionless Gas
    
    Mendeleev Commun., 24:5 (2014),  308–310
40. Influence of humidity on the combustion of powdered and granulated Ti + 0.5C mixtures
    
    Mendeleev Commun., 24:4 (2014),  242–244
41. Influence of an acoustic resonator on flame propagation regimes in spark initiated H₂ combustion in a cylindrical reactor near the lower detonation limit
    
    Mendeleev Commun., 24:1 (2014),  50–52
42. Cellular combustion at the transition of a spherical flame front to a flat front at the initiated ignition of methane–air, methane–oxygen and n-pentane–air mixtures
    
    Mendeleev Commun., 23:6 (2013),  358–360
43. Interaction of the Laminar Flames of Methane–air Mixtures with Close-meshed Spherical and Planar Obstacles in a Closed Cylindrical Reactor Under Spark Discharge Initiation
    
    Mendeleev Commun., 23:3 (2013),  163–165
44. Investigation into Spontaneous Ignition of Hydrogen–air Mixtures in a Heated Reactor at Atmospheric Pressure by High-speed Cinematography
    
    Mendeleev Commun., 22:4 (2012),  222–224
45. Suppression of the ignition of coal powders in the presence of oxygen and natural gas with small additives of octadecafluorodecahydronaphthalene vapour
    
    Mendeleev Commun., 22:3 (2012),  154–156
46. Investigation into the ignition of coal powders in the presence of oxygen and natural gas by means of high-speed cinematography
    
    Mendeleev Commun., 22:1 (2012),  47–49
47. Initiation and propagation of laminar spherical flames at atmospheric pressure†
    
    Mendeleev Commun., 21:4 (2011),  218–220
48. Investigation into the combustion of lean hydrogen–air mixtures at atmospheric pressure by means of high-speed cinematography
    
    Mendeleev Commun., 21:4 (2011),  215–217
49. High-speed colour cinematography of the spontaneous ignition of propane–air and n-pentane–air mixtures
    
    Mendeleev Commun., 21:1 (2011),  31–33
50. Formation of threadlike nanostructures of silicon and silicon carbide by chemical vapor deposition
    
    Mendeleev Commun., 20:6 (2010),  357–358
51. Concentration limits of combustion in rich hydrogen–air mixtures in the presence of inhibitors
    
    Mendeleev Commun., 20:5 (2010),  296–298
52. Thermal ignition of coal powders in the presence of natural gas, oxygen and chemically active additives
    
    Mendeleev Commun., 20:2 (2010),  98–100
53. Investigation into self-ignition in chain oxidation of hydrogen, natural gas and isobutene by means of high-speed colour cinematography
    
    Mendeleev Commun., 19:6 (2009),  346–349
54. Features of initiation of spherical flames in mixtures of natural gas and isobutylene with oxygen in the presence of inert additives
    
    Mendeleev Commun., 19:4 (2009),  230–232
55. On the nature of an upper concentration limit of flame propagation in an H₂+air mixture
    
    Mendeleev Commun., 19:4 (2009),  227–229
56. Gaseous nature of the reaction of Si–N bond formation in self-propagation high-temperature synthesis of silicon nitride by means of an azide method
    
    Mendeleev Commun., 19:1 (2009),  45–46
57. О возможности теплового взрыва, инициированного гетерогенной реакцией H$_2$ с О$_2$
    
    Физика горения и взрыва, 44:6 (2008),  130–134
58. Thermal ignition of coal–gas suspensions containing natural gas and oxygen
    
    Mendeleev Commun., 18:6 (2008),  340–341
59. Numerical investigation of the effects of surface recombination and initiation for laminar hydrogen flames at atmospheric pressure
    
    Mendeleev Commun., 18:4 (2008),  220–222
60. Flame propagation limits in H₂+air mixtures in the presence of small inhibitor additives
    
    Mendeleev Commun., 18:2 (2008),  105–108
61. Influence of Cr(CO)₆ and Mo(CO)₆ on the critical conditions for ignition and the velocities of flame propagation for the chain-branching oxidation of hydrogen and propylene
    
    Mendeleev Commun., 16:5 (2006),  282–284
62. Kinetic regularities of solid-phase formation in the branching chain reaction of dichlorosilane oxidation in rf plasma at low pressures and 293 K
    
    Mendeleev Commun., 16:1 (2006),  38–40
63. Кинетические режимы развившегося цепного горения
    
    Физика горения и взрыва, 39:3 (2003),  127–137
64. Inhibition and promotion of an isothermal flame in the low-pressure thermal decomposition of nitrogen trichloride
    
    Mendeleev Commun., 12:6 (2002),  241–244
65. Dichlorosilane chlorination in the presence of propylene as an inhibitor at low pressures and 293 K
    
    Mendeleev Commun., 12:1 (2002),  37–39
66. Transition from isothermal to chain-thermal flame-propagation regimes in the branching-chain decomposition of nitrogen trichloride
    
    Mendeleev Commun., 12:1 (2002),  33–36
67. On the nature of the upper limit of isothermal flame propagation in the branching-chain decomposition of nitrogen trichloride
    
    Mendeleev Commun., 11:2 (2001),  61–64
68. Effect of chemically active additives on the velocity of detonation waves and on the limit of gaseous detonation
    
    Mendeleev Commun., 10:6 (2000),  225–227
69. NIR investigation of the rarefied flame of dichlorosilane oxidation at low pressures and 293 K
    
    Mendeleev Commun., 10:4 (2000),  143–145
70. Kinetic mechanism and chemical oscillations in the branching chain decomposition of nitrogen trichloride
    
    Mendeleev Commun., 8:5 (1998),  173–176
71. Detection of SiH₂ from the A¹B₁–X¹A₁ transition in the emission spectrum of the rarified flame in the oxidation of silane
    
    Mendeleev Commun., 7:5 (1997),  187–188
72. Нетепловое распространение пламени треххлористого азота
    
    Физика горения и взрыва, 15:5 (1979),  34–40
73. Кинетические закономерности распада NCl$_3$ в условиях разреженного пламени
    
    Физика горения и взрыва, 14:2 (1978),  20–25