Shuvalov Valentin Alekseevich

Publications in Math-Net.Ru

1. Electron saturation current on a cylindrical probe in a magnetized rarefied plasma flow
   
   TVT, 60:1 (2022),  3–10
2. Braking of a magnetized body at the interaction of its magnetic field with a rarified plasma flow
   
   TVT, 58:2 (2020),  163–174
3. Braking of a “magnetized” sphere in a hypersonic rarefied plasma flow
   
   TVT, 56:4 (2018),  490–498
4. Dynamicinteraction of a magnetized solid body with a rarefied plasma flow
   
   Prikl. Mekh. Tekh. Fiz., 57:1 (2016),  167–175
5. Management of the dynamic interaction of a "magnatized" sphere with a hypersonic flow of rarefied plasma
   
   TVT, 53:4 (2015),  487–493
6. Dynamic interaction of a “magnetized” cone with a hypersonic flow of rarefied plasma
   
   TVT, 51:6 (2013),  803–810
7. Physical simulation of the interaction effects of Magnetized bodies and the Earth’s atmosphere in a hypersonic rarefied plasma flow
   
   TVT, 50:3 (2012),  337–345
8. Heat exchange and deceleration of a magnetized body in a rarefied plasma flow
   
   Prikl. Mekh. Tekh. Fiz., 52:1 (2011),  3–12
9. Control over Heat Exchange and Deceleration of a “Magnetized” Body in a Rarefied Plasma Flow
   
   TVT, 49:3 (2011),  343–351
10. Diagnostics of Nonequilibrium Collisional Plasma with a Thermoanemometric Probe
    
    TVT, 49:1 (2011),  28–35
11. Contact Diagnostics of High-Velocity Flows of Rarefied Plasma
    
    TVT, 43:3 (2005),  343–351
12. The structure of clusters and jets of pulsed plasma expanding into vacuum
    
    TVT, 42:1 (2004),  23–30
13. Diagnostics of flows of pulsed plasma by probe, microwave, and photometric methods
    
    TVT, 38:6 (2000),  877–881
14. Probe diagnosis of a flow of particles desorbed from the surface of a solid by a low-density plasma jet
    
    Prikl. Mekh. Tekh. Fiz., 34:5 (1993),  144–150
15. MHD deceleration and heat transfer for a sphere in a supersonic flow of partially ionized gas
    
    Prikl. Mekh. Tekh. Fiz., 32:1 (1991),  15–19
16. Resistance of a body with an intrinsic magnetic field in a supersonic flow of a partially ionized gas
    
    Prikl. Mekh. Tekh. Fiz., 31:1 (1990),  50–55
17. Transferring the energy of atomic ions from a supersonic flow of a partially dissociated gas to the surface of a solid
    
    Prikl. Mekh. Tekh. Fiz., 30:6 (1989),  11–19
18. Exchange of energy and momentum between ions in a rarefied-plasma flow and an electrically conducting surface coated with a thin-layer of dielectric
    
    TVT, 25:4 (1987),  644–648
19. Transfer of gas-ion momentum and energy to an electrically conductive surface partially coated by a thin dielectric layer
    
    Prikl. Mekh. Tekh. Fiz., 27:4 (1986),  8–16
20. Effect of surface potential and intrinsic magnetic field on resistance of a body in a supersonic flow of rarefied partially ionized gas
    
    Prikl. Mekh. Tekh. Fiz., 27:3 (1986),  41–47
21. Energy accommodation of ions from a flux of rarefied plasma on a metal-surface partially covered by a layer of dielectric
    
    TVT, 24:6 (1986),  1067–1071
22. EFFECT OF CHARACTERISTIC A MAGNETIC-FIELD ON THE STRUCTURE OF A DISTURBED ZONE AROUND THE BODY IN A STREAM OF EVACUATED PLASMA
    
    Zhurnal Tekhnicheskoi Fiziki, 54:6 (1984),  1107–1114
23. Transfer of the momentum of gas ions to the surface of a solid
    
    Prikl. Mekh. Tekh. Fiz., 25:3 (1984),  24–32
24. Determination of the interaction parameters of ions from a rarefied plasma-flow with electrically conducting surfaces using thermoanemometric probes
    
    TVT, 22:6 (1984),  1172–1177
25. Determination of the integrated emissivity of conducting materials by means of hot-wire probes
    
    TVT, 22:3 (1984),  492–495
26. О влиянии молекулярной массы газовых ионов на аккомодацию энергии на поверхностях технических материалов
    
    TVT, 21:5 (1983),  1016–1018
27. Investigation of the plasma structure formed on the surface of a body in flow of a partially ionized gas
    
    Prikl. Mekh. Tekh. Fiz., 22:2 (1981),  48–54
28. Effect of structure of plasma formations near the surface of an object on scattering of electromagnetic-waves in a flow of partially ionized-gas
    
    TVT, 19:4 (1981),  729–734
29. Исследование параметров взаимодействия потока разреженной плазмы с электропроводящими поверхностями с помощью термоанемометрических зондов
    
    TVT, 19:3 (1981),  649–651
30. Influence of orientation of a thermal anemometer probe on the ion-energy accommodation coefficient in rarefied plasma-flow
    
    TVT, 19:2 (1981),  386–390
31. Parameters of plasma formations at the surface of a sphere in an attenuated-plasma flow
    
    TVT, 19:1 (1981),  109–113
32. Effect of angle of attack of a metal surface element on the energy accomodation coefficient of nitrogen ions
    
    Prikl. Mekh. Tekh. Fiz., 21:3 (1980),  31–35
33. Influence of target orientation on the energy accommodation coefficient for nitrogen ions
    
    Prikl. Mekh. Tekh. Fiz., 21:1 (1980),  102–104
34. Energy accomodation coefficients of positive ions in a low-density plasma flow on the surfaces of certain materials
    
    Prikl. Mekh. Tekh. Fiz., 20:6 (1979),  115–118
35. Influence of the atomic weight of the target on the magnitude of the energy accommodation coefficient of ions of a partially ionized gas flow
    
    Prikl. Mekh. Tekh. Fiz., 20:3 (1979),  83–87
36. Применение термоанемометрических зондов для измерения коэффициентов аккомодации энергии ионов потока разреженной плазмы
    
    TVT, 16:5 (1978),  931–936
37. Об определении степени неизотермичности потока разреженной плазмы зондовыми методами
    
    TVT, 16:4 (1978),  688–692
38. О диагностике струи разреженной плазмы с применением зондового и СВЧ-методов
    
    TVT, 16:1 (1978),  9–12
39. Генерирование плазменных образований у поверхности тел в потоке частично ионизованного газа
    
    TVT, 15:4 (1977),  896–898
40. Об определении плотности заряженных частиц в неравновесной разреженной плазме по характеристике зонда Лэнгмюра
    
    TVT, 10:3 (1972),  642–643
41. Investigation of parameters of a high-frequency discharge in a magnetic field in the presence of a gas flow
    
    TVT, 9:3 (1971),  631–633
42. Применение термоанемометра – зонда Ленгмюра для диагностики разреженной плазмы
    
    TVT, 7:5 (1969),  866–872


43. О применении термоанемометрических зондов для исследования энергообмена потока разреженного частично ионизованного газа с сетчатыми поверхностями (№ 7512-86 Деп. от 31.Х.1986)
    
    TVT, 25:2 (1987),  413
44. О влиянии плазменных образований на рассеяние электромагнитных волн металлическим телом в потоке частично ионизованного газа (№ 6227-84 Деп. от 13.IX.1984)
    
    TVT, 23:1 (1985),  199
45. О диагностике разреженной плазмы с применением зондового и фотометрического методов (№ 488-79 Деп. от 6.II.1979)
    
    TVT, 17:2 (1979),  444
46. Плазменная газодинамическая установка для моделирования движения тел в ионосфере (№ 4394-76 Деп. от 20/XII 1976)
    
    TVT, 15:2 (1977),  442