Raizer Yurii Petrovich

Publications in Math-Net.Ru

1. Filling of a plane slit volume with a glow discharge in a transverse magnetic field and its effect on the discharge contraction
   
   Zhurnal Tekhnicheskoi Fiziki, 88:6 (2018),  832–842
2. Reduction of drag and energy consumption during energy release preceding a blunt body in supersonic flow
   
   TVT, 42:6 (2004),  890–899
3. The mechanism of lightning attraction and the problem of lightning initiation by lasers
   
   UFN, 170:7 (2000),  753–769
4. The calculation and similarity theory of experiment simulating the air-spike effect in hypersonic aerodynamics
   
   TVT, 36:2 (1998),  304–309
5. Streamer channel intergrowth: The field and density of plasma behind the ionization wave and initiating electrons before it
   
   TVT, 35:2 (1997),  181–186
6. The nonmonotonicity of transition from Faraday dark space to positive column and the emergence of standing strata behind the cathode region of glow discharge
   
   TVT, 35:1 (1997),  19–24
7. Laser combustion waves in Laval nozzles
   
   TVT, 33:1 (1995),  13–23
8. Mathematical model of gasdischarge and heat processes in technological lasers chamber
   
   Mat. Model., 5:3 (1993),  32–58
9. The rate of current spot expansion on a glow discharge cathode upon abrupt voltage rise
   
   TVT, 31:1 (1993),  22–28
10. Three-dimensional computational mhd-model of plasma expansion into non-uniform medium with magnetic field
    
    Mat. Model., 4:7 (1992),  49–66
11. Localized explosion in a material with a magnetic field and the consequences of finite conductivity in a magnetohydrodynamic model
    
    Prikl. Mekh. Tekh. Fiz., 32:3 (1991),  22–28
12. Longitudinal structure of the cathode portions of glow discharges
    
    TVT, 29:6 (1991),  1041–1052
13. Observed velocity of slow motion of an optical discharge
    
    Kvantovaya Elektronika, 17:7 (1990),  937–942
14. Charge diffusion along a current and an effective method of eliminating computational for glow discharges
    
    TVT, 28:3 (1990),  439–443
15. Electrodeless capacitive discharge sustained by repetitive high-voltage pulses
    
    TVT, 27:3 (1989),  431–438
16. Continuous optical discharge burning at elevated pressures
    
    Kvantovaya Elektronika, 15:3 (1988),  551–553
17. Two-dimensional structure in a normal glow-discharge and diffusion effects in cathode and anode spot formation
    
    TVT, 26:3 (1988),  428–435
18. Nature of the effect of normal current-density on a glow-discharge cathode
    
    Pisma v Zhurnal Tekhnicheskoi Fiziki, 13:8 (1987),  452–456
19. О возможностях расширения области существования высокочастотного разряда с непроводящими приэлектродными слоями
    
    TVT, 25:5 (1987),  1008–1009
20. Two-dimensional calculations of a continuous optical discharge in atmospheric-air flow (optical plasmatron)
    
    TVT, 25:3 (1987),  454–461
21. Presonic gas eddy under conditions of intensive energy isolation in the optical plasmatron
    
    Pisma v Zhurnal Tekhnicheskoi Fiziki, 12:3 (1986),  134–138
22. Two-dimensional calculation of the temperature field of a continuous optical discharge in air
    
    Kvantovaya Elektronika, 13:3 (1986),  593–600
23. The current level of understanding of phenomena in the cathode regions of glow-discharges
    
    TVT, 24:5 (1986),  984–994
24. Self-sustained and non-self-sustained glow-discharges in a gas-flow
    
    TVT, 24:2 (1986),  233–238
25. Numerical study of a continuous optical discharge in atmospheric air in the framework of a one-dimensional model
    
    TVT, 23:1 (1985),  29–35
26. Investigation of the processes occurring in an optical plasmatron by numerical calculation
    
    Kvantovaya Elektronika, 11:11 (1984),  2301–2310
27. Linearized one-dimensional model of optical plasmatron operation
    
    Kvantovaya Elektronika, 11:1 (1984),  64–72
28. A noncontradictory method for calculation of radiant transfer and the question of shock wave structure
    
    Prikl. Mekh. Tekh. Fiz., 24:6 (1983),  42–47
29. Rapid-flow combined-action industrial CO₂ laser
    
    Kvantovaya Elektronika, 9:8 (1982),  1549–1557
30. Optical discharges
    
    UFN, 132:3 (1980),  549–581
31. К вопросу о каналовой модели дуги
    
    TVT, 17:5 (1979),  1096–1098
32. A simple theory of breakdown of monatomic nonlight gases in fields of any frequency from low to optical
    
    Prikl. Mekh. Tekh. Fiz., 14:1 (1973),  40–47
33. О недостающем уравнении каналовой модели дуги, которое заменяет условие минимума напряжения
    
    TVT, 10:6 (1972),  1152–1155
34. Propagation of discharges and maintenance of a dense plasma by electromagnetic fields
    
    UFN, 108:3 (1972),  429–463
35. Structure of a shock wave in which multiple ionization of the atoms is taking place
    
    Prikl. Mekh. Tekh. Fiz., 11:5 (1970),  11–21
36. Creation of nonequilibrium states and change of plasma absorptivity under the action of powerful light pulses
    
    Prikl. Mekh. Tekh. Fiz., 11:3 (1970),  27–37
37. Nonlinear absorption of laser pulses by a partially ionized gas
    
    Prikl. Mekh. Tekh. Fiz., 11:1 (1970),  142–146
38. Письмо в редакцию “Успехов физических наук”
    
    UFN, 101:3 (1970),  569
39. Physical principles of the theory of brittle fracture cracks
    
    UFN, 100:2 (1970),  329–347
40. High-frequency high-pressure induction discharge and the electrodeless plasmotron
    
    UFN, 99:4 (1969),  687–712
41. A high-frequency high-pressure gas flow discharge as a slow combustion process
    
    Prikl. Mekh. Tekh. Fiz., 9:3 (1968),  3–10
42. Ionization relaxation behind the front of a shock wave in argon with air impurities
    
    Prikl. Mekh. Tekh. Fiz., 9:1 (1968),  140–145
43. Recombination of electrons in a plasma expanding into a vacuum
    
    Prikl. Mekh. Tekh. Fiz., 6:4 (1965),  10–20
44. Breakdown and heating of gases under the influence of a laser beam
    
    UFN, 87:1 (1965),  29–64
45. Тормозное излучение электрона при рассеянии нейтральными атомами с учетом корреляции столкновений
    
    Prikl. Mekh. Tekh. Fiz., 5:5 (1964),  149–151
46. Распространение ударной волны в неоднородной атмосфере в сторону уменьшения плотности
    
    Prikl. Mekh. Tekh. Fiz., 5:4 (1964),  49–56
47. Замечание о разлете газового облака в пустоту
    
    Prikl. Mekh. Tekh. Fiz., 5:3 (1964),  162–163
48. Motion produced in an inhomogeneous atmosphere by a plane shock of short duration
    
    Dokl. Akad. Nauk SSSR, 153:3 (1963),  551–554
49. О торможении и превращениях энергии плазмы, расширяющейся в пустом пространстве, в котором имеется магнитное поле
    
    Prikl. Mekh. Tekh. Fiz., 4:6 (1963),  19–28
50. Движение газа под действием сосредоточенного удара по его поверхности (при взрыве на поверхности)
    
    Prikl. Mekh. Tekh. Fiz., 4:1 (1963),  57–66
51. Ударные волны большой амплитуды в газах
    
    UFN, 63:3 (1957),  613–641


52. Методы численного расчета двумерного течения в оптическом плазмотроне (№ 7510-86 Деп. от 31.Х.1986)
    
    TVT, 25:2 (1987),  412
53. Одномерная численная модель оптического плазмотрона (№ 4705-84 от 4.VII.1984)
    
    TVT, 22:6 (1984),  1233
54. First All-Union Conference and School on Applications of Lasers in Machine Construction and Other Branches of Technology and on Physical Aspects of the Development of Gas Lasers, Moscow, June 17–21,1974
    
    Kvantovaya Elektronika, 2:2 (1975),  445–449