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11 September 2006
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I. THEORY, MODELLING AND DIAGNOSTICS |
1. |
E. Benova
(University of Sofia, Sofia, Bulgaria)
Self-consistent modelling of surface-wave-sustained
discharges from low to atmospheric pressures.
(23 kb)
(plenary)
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2. |
H. Hojo, N. Uchida, Y. Yasaka* and A. Mase**
(Plasma Research Center, University of Tsukuba, Tsukuba, Japan,
*Faculty of Engineering, Kobe University, Kobe, Japan,
**Art, Science and Technology Center for Cooperative Research,
Kyushu University, Kasuga, Japan)
Theory of surface waves in non-uniform plasmas with plasma resonance.
(23 kb)
(plenary)
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3. |
A.L. Vikharev
(Institute of Applied Physics RAS, Nizhny Novgorod, Russia)
Physics and application of gas discharge in millimeter wave
beams.
(20 kb)
(plenary)
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4. |
D. Khmara, Yu. Kolesnichenko
(IHT RAS, Moscow)
Modeling of microwave field interaction with decaying laser
spark in air.
(22 kb)
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5. |
F.M. Dias* and Tsv. Ppopv**
(*Centro de Fisica dos Plasmas, Instituto Superior Tecnico,
1049-001 Lisboa, Portugal,
**St. Kliment Ohridski University of Sofia, Faculty of Physics,
J. Bourchier, 1164-Sofia, Bulgaria)
EEDF probe measurements: a contribution towards the
ultimate differentiating system.
(22 kb)
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6. |
Simon Letout, Philippe Leprince, Lionel Teule-Gay, Caroline Boisse-Laporte
(Laboratoire de Physique des Gaz et Plasmas, Univ. Paris-Sud XI, Orsay,
France)
Hot anisotropic electron population in a low-pressure
coaxial microwave discharge.
(37 kb)
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7. |
J. Torres, J.M. Palomares, A. Sola, J.J.A.M. van der Mullen* and
A. Gamero
(Universidad de Cordoba, Cordoba, Spain, *Eindhoven University of
Technology, The Netherlands)
A novel Stark broadening method to measure the
electron temperature and density simultaneously in high-pressure microwave
plasmas.
(21 kb)
(plenary)
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8. |
Yu.A. Lebedev, I.L. Epstein, A.V. Tatarinov
(A.V. Topchiev Institute of Petrochemical Synthesis, Moscow, Russia)
Modeling of electrode microwave discharge in hydrogen and
nitrogen.
(24 kb)
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9. |
R. Álvarez, A. Rodero, M.C. Quintero, S. Rubio
(Department of Physics, University of Córdoba, Córdoba, Spain)
A collisional-radiative model for an atmospheric
pressure microwave argon plasma.
(21 kb)
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10. |
N.A. Azarenkov, Vl.V. Gushchin, V.V. Gushchin
(Physical Technical department, V.N.Karazin national university, 61108,
Kharkov, Ukraine)
Comparison collisionless mechanisms of absorption
of energy in discharges sustained by surface waves at low pressure.
(21 kb)
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11. |
S. Dvinin, A. Vologirov*, V. Mikheev, V. Sviridkina
(Lomonosov Moscow State University, Physics department, Moscow, Russia,
*Open Company "Radiating safety and ecology", Moscow, Russia)
High frequency surface waves on plasma - metal
boundary.
(23 kb)
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12. |
V.M. Shibkov, A.F. Aleksandrov, V.A. Chernikov, A.P. Ershov,
R.S. Konstantinovskij, L.V. Shibkova, V.V. Zlobin
(Physical Faculty of the Moscow State University, 119992 Moscow, Russia)
Freely localized and surface microwave discharges in
high-speed flows.
(22 kb)
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13. |
I.R. Rafatov
(Middle East Technical University, TR-06531 Ankara, Turkey)
Modelling of a nonequilibrium spherical electric discharge
under higher modes of incident microwaves.
(22 kb)
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