Batenin Vyacheslav Mikhailovich

Publications in Math-Net.Ru

1. Thermodynamics of melts based on the processing technology of the richest rare metal ores of Tomtor deposit
   
   TVT, 58:4 (2020),  634–640
2. Comparative analysis of the efficiency of alternative electric and thermal technologies of natural gas energy production
   
   TVT, 56:3 (2018),  461–468
3. Copper vapor laser pumped by pulse-periodic high-frequency discharge
   
   TVT, 55:5 (2017),  678–684
4. Improvement of thermodynamic efficiency of the humid biofuel application in the distributed generation power suppliers
   
   TVT, 55:1 (2017),  76–80
5. Evolution of diffraction pattern of probing radiation reflected by a silver surface upon melting
   
   TVT, 54:2 (2016),  294–297
6. Modernization of the experimental base for studies of MHD heat transfer at advanced nuclear power facilities
   
   TVT, 53:6 (2015),  934–937
7. On the technology for effective utilization of humid fuels
   
   TVT, 53:3 (2015),  475–477
8. Dust reactor for limestone calcination
   
   TVT, 53:2 (2015),  301–311
9. New technologies for distributed energetics
   
   TVT, 53:1 (2015),  111–116
10. A steam–gas power plant for combined generation of electricity, heat, and cold (trigeneration)
    
    TVT, 52:6 (2014),  934–940
11. Output energy parameters of a KULON-10Cu-UV laser
    
    Kvantovaya Elektronika, 39:5 (2009),  405–409
12. Efficient sum-frequency and second harmonic generation in a two-pass copper vapour laser amplifier
    
    Kvantovaya Elektronika, 35:9 (2005),  844–848
13. A stationary vacuum arc with a diffuse spot on a nonemitting chrome cathode
    
    TVT, 41:5 (2003),  670–678
14. Production of an extended plasma column in vacuum by irradiating a target by a quasi-Bessel beam
    
    Kvantovaya Elektronika, 31:5 (2001),  448–452
15. Laser-monitor-assisted investigation of the regions of closure of current on the electrodes of an atmospheric-pressure low-current carbon arc
    
    TVT, 39:5 (2001),  794–809
16. To the readers of the journal
    
    TVT, 36:4 (1998),  533
17. Development of technological and power-generating solar facilities: New approach
    
    TVT, 35:5 (1997),  807–814
18. Зеркальные экраны как средство увеличения эффективной поглощательной и уменьшения эффективной излучательной способностей тел, нагреваемых излучением
    
    TVT, 30:2 (1992),  426–428
19. Prospects for development of cw gas-discharge collision lasers based on self-terminating atomic transitions
    
    Kvantovaya Elektronika, 18:2 (1991),  189–194
20. Application of optical systems with intensity amplifiers for investigation of surfaces of graphite and pyrographite electrodes during burning of an arc
    
    TVT, 29:6 (1991),  1204–1210
21. Interaction of a surface with its vapor plasma after the termination of a laser pulse
    
    TVT, 28:6 (1990),  1093–1100
22. Radial inhomogeneities of the active medium plasma parameters in a self-heated copper vapor laser during the interpulse period
    
    Kvantovaya Elektronika, 16:11 (1989),  2216–2224
23. Feasibility of measuring the absolute temperature distribution of the surface of ceramic samples by a luminescence thermal imaging method
    
    TVT, 27:5 (1989),  976–979
24. Evolution of the state of inert-gas beam plasmas – transient plasmas
    
    TVT, 27:4 (1989),  625–635
25. Possibility of measuring the absolute temperature of ceramics by the method of laser-induced luminescence
    
    TVT, 27:2 (1989),  347–351
26. Calculation of the parameters of cw lasing due to 2p–1s atomic transitions excited by discharges in pure rare gases
    
    Kvantovaya Elektronika, 15:10 (1988),  1981–1984
27. Investigation of quasi-cw lasing due to a self-terminating transition of the calcium atom in a hollow-cathode discharge
    
    Kvantovaya Elektronika, 14:11 (1987),  2162–2167
28. Collective effects in and anomalous conductivity of a nonideal current-conducting plasma – evolution of strata at the plasma stage of the discharge – buildup of superthermal Langmuir noise
    
    TVT, 25:3 (1987),  417–423
29. Collective effects and anomalous conductivity in a nonideal current-carrying plasma – physical model – stratification of a current-carrying conductor
    
    TVT, 25:2 (1987),  218–224
30. Energy characteristics of cw gas-discharge lasers utilizing self-terminating atomic transitions. II. Calculation of lasing characterisics
    
    Kvantovaya Elektronika, 13:11 (1986),  2236–2242
31. Energy characteristics of cw gas-discharge lasers utilizing self-terminating atomic transitions. I. Experimental investigation of quasi-cw barium vapor lasers
    
    Kvantovaya Elektronika, 13:11 (1986),  2228–2235
32. Evolution of the states of an inert-gas beam-plasma – effect of heating of the gas
    
    TVT, 24:2 (1986),  218–222
33. State evaluation in an inert-gas beam-plasma – cold quasi-stationary plasma
    
    TVT, 24:1 (1986),  9–20
34. Characteristics of a MHD generator operating away from its nominal conditions – the R1 channel in the U-25 plant
    
    TVT, 23:4 (1985),  798–806
35. Временные характеристики излучения пучковой плазмы $\mathrm{Xe}$
    
    TVT, 23:1 (1985),  173–174
36. Features of the local current and potential distributions in a diagonal MHD channel
    
    TVT, 22:3 (1984),  593–599
37. Gas-dynamic and electrical characteristics of MHD generator according to data from physical and numerical experiments – RM channel of the U-25 device
    
    TVT, 21:3 (1983),  567–576
38. О применимости метода резонансной флуоресценции для локального исследования плазмы МГД-генератора
    
    TVT, 21:1 (1983),  183–186
39. Emission spectra of the $\mathrm{Xe}$ beam plasma
    
    Dokl. Akad. Nauk SSSR, 266:5 (1982),  1108–1112
40. Quasi-cw lasing due to transitions from the resonance ¹P₁ to the metastable ¹D₂ level of the calcium atom
    
    Kvantovaya Elektronika, 9:10 (1982),  2075–2077
41. Influence of electron heating during recombination of copper atoms in copper halide vapor lasers on their output parameters
    
    Kvantovaya Elektronika, 9:7 (1982),  1313–1317
42. Radial-distribution of the plasma parameters in the afterglow from a periodic high-voltage pulsed discharge in mixtures of bismuth vapor with inert-gases
    
    TVT, 20:5 (1982),  806–811
43. Распределение атомов и молекул по радиусу разрядной трубки в лазере на парах галогенидов меди
    
    TVT, 20:3 (1982),  580–582
44. Investigation of boundary-layers in a MHD generator plasma using the electric probe method
    
    TVT, 20:2 (1982),  229–235
45. К.П.Д. лазеров на парах меди
    
    TVT, 20:1 (1982),  177–180
46. On the poly parametric optimization of copper-vapor lasers
    
    Dokl. Akad. Nauk SSSR, 256:4 (1981),  831–834
47. Infrared emission from a lead vapor laser
    
    Kvantovaya Elektronika, 8:5 (1981),  1098–1100
48. Feasibility of a solar-radiation-pumped color-center crystal laser
    
    Kvantovaya Elektronika, 8:3 (1981),  634–636
49. О возможности получения непрерывной генерации на самоограниченных переходах в электрическом разряде
    
    TVT, 19:6 (1981),  1304–1306
50. Parameters of collisional lasers based on self-limited transitions with optical-pumping
    
    TVT, 19:5 (1981),  937–944
51. Some features of atmospheric-pressure discharges with the combined action of constant and VHF electric-fields (combined discharges)
    
    TVT, 19:2 (1981),  240–245
52. Kinetics of recombination of copper atoms in copper halide vapor lasers
    
    Kvantovaya Elektronika, 7:8 (1980),  1813–1820
53. Plasma parameters in the afterglow of a copper vapor laser
    
    Kvantovaya Elektronika, 7:5 (1980),  988–992
54. Some Features of Atmospheric Pressure Discharges Acted on by Combined de and uhf Electric Fields (Combined Discharges) Plasma Parameters and Electric Characteristics of a Combined Discharge
    
    TVT, 18:6 (1980),  1137–1143
55. Limiting Mean Power Output from a Copper-Vapor Laser
    
    TVT, 18:4 (1980),  707–712
56. Possibility of obtaining efficient cw stimulated emission from optically pumped lasers utilizing self-terminating transitions
    
    Kvantovaya Elektronika, 6:5 (1979),  1077–1080
57. Спектральный состав индуцированного излучения лазера на парах меди и его временная эволюция
    
    TVT, 17:3 (1979),  483–489
58. Неоднородность разряда в лазере на парах меди
    
    TVT, 17:1 (1979),  208–209
59. Температура газа в лазере на парах меди
    
    TVT, 16:6 (1978),  1145–1151
60. Time dependence of the electron density in a copper vapor laser
    
    Kvantovaya Elektronika, 4:7 (1977),  1572–1575
61. Подавление ионнозвуковой столкновительной неустойчивости газоразрядной замагниченной плазмы СВЧ-электромагнитным полем
    
    TVT, 15:4 (1977),  722–727
62. К вопросу об излучении плотной низкотемпературной плазмы инертных газов
    
    TVT, 15:3 (1977),  647–649
63. Диагностика низкотемпературной плазмы по рассеянию излучения аргонового лазера
    
    TVT, 15:2 (1977),  239–246
64. Role of buffer gases in lasers working on copper vapors
    
    TVT, 14:6 (1976),  1316–1319
65. Microwave-discharge in helium
    
    TVT, 14:1 (1976),  209–211
66. Спектроскопические исследования СВЧ-разряда в водороде
    
    TVT, 13:2 (1975),  270–278
67. О высокотемпературном состоянии плазмы в мощном СВЧ-разряде
    
    TVT, 11:2 (1973),  407–409
68. Влияние СВЧ-поля на неоднородности неравновесной плазмы газового разряда низкого давления
    
    TVT, 11:1 (1973),  19–27
69. Стабилизированный магнитным полем СВЧ-разряд
    
    TVT, 9:6 (1971),  1289–1290
70. Стационарный СВЧ-разряд в азоте при атмосферном давлении
    
    TVT, 9:6 (1971),  1105–1112
71. Экспериментальное исследование движения фронта ионизации в СВЧ-электромагнитном поле
    
    TVT, 9:5 (1971),  896–900
72. Об особенностях поведения электропроводности и излучения плотной низкотемпературной плазмы
    
    TVT, 9:4 (1971),  676–682
73. Determination of the rate of movement of the drops of a two-phase flow using the transit-time method
    
    TVT, 8:4 (1970),  863–867
74. Experimental investigation of the electrical conductivity of a $\mathrm{He}$–$\mathrm{K}$ plasma
    
    TVT, 8:2 (1970),  441–442
75. Экспериментальное исследование тормозного излучения электронов в поле атомов $\rm{Ar}$
    
    TVT, 7:5 (1969),  832–835
76. Непрерывное излучение низкотемпературной плазмы аргона
    
    TVT, 7:4 (1969),  604–609
77. Диагностика плазмы слаботочного дугового разряда при помощи светового зонда (II)
    
    TVT, 7:3 (1969),  401–407
78. О температуре на оси электрической дуги в аргоне
    
    TVT, 7:2 (1969),  208–212
79. Диагностика плазмы слаботочного дугового разряда при помощи светового зонда
    
    TVT, 6:6 (1968),  981–988
80. К расчету электропроводности частично ионизованной плазмы
    
    TVT, 6:6 (1968),  966–972
81. Экспериментальное исследование непрерывного спектра плазмы аргона
    
    TVT, 3:4 (1965),  530–535


82. Vladislav Yur'evich Khomich (on his 70th birthday)
    
    UFN, 192:4 (2022),  453–454
83. A review of the monograph "Copper Vapour Lasers: Design, Characteristics and Applications" by A. G. Grigor'yants, M. A. Kazaryan and N. A. Lyabin (Moscow: Fizmatlit, 2005, 312 pp.)
    
    Kvantovaya Elektronika, 35:5 (2005),  484
84. In memory of Anatolii Pavlovich Nefedov
    
    UFN, 171:5 (2001),  573–574
85. In memory of Leon Mikhailovich Biberman
    
    UFN, 169:1 (1999),  111–112
86. Sergei Vladimirovich Lebedev (Obituary)
    
    UFN, 161:3 (1991),  181–183
87. Errata to the article: Energy characteristics of cw gas-discharge lasers utilizing self-terminating atomic transitions. I. Experimental investigation of quasi-cw barium vapor lasers
    
    Kvantovaya Elektronika, 14:4 (1987),  896