Ionization degree for strong evaporation of metals
- Baikov Institute of Metallurgy, Russian Academy of Sciences, Leninsky Prospect 49, 119991 Moscow (Russian Federation)
Kinetic equations for ions and neutrals are numerically solved in the plasma sheath formed at a condensed phase when strong evaporation is taking place. The Boltzmann distribution is assumed for electrons. A weakly ionized vapor with the Debye length much shorter than the mean free path is considered. This is typical for laser evaporation of metals. Under these conditions, the sheath consists of a Knudsen layer and a thin charge separation layer between the Knudsen layer and the condensed phase. The self-consistent electrostatic field in the Knudsen layer is obtained from the quasineutrality condition. The potential barrier in the charge separation layer is determined by the charge balance. Kinetic boundary conditions for neutrals and charges are estimated by the detailed balance principle from the parameters of the saturated vapor. The transport of charges in the sheath is controlled by ions and depends on ion-neutral collisions and the self-consistent electrostatic field. Ionization degree in the vapor formed by strong evaporation increases with the Mach number and can attain values about 30% higher than the ionization degree in the saturated vapor. Two factors contribute to this increase. The first is the drop of the potential barrier in the charge separation layer and the second is the strengthening of the field in the Knudsen layer. The ionization equilibrium may be disturbed by a considerable excess of charges.
- OSTI ID:
- 20764487
- Journal Information:
- Physics of Plasmas, Vol. 12, Issue 8; Other Information: DOI: 10.1063/1.2002229; (c) 2005 American Institute of Physics; Country of input: International Atomic Energy Agency (IAEA); ISSN 1070-664X
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
BOUNDARY CONDITIONS
CHARGED-PARTICLE TRANSPORT
DEBYE LENGTH
DETAILED BALANCE PRINCIPLE
DISTRIBUTION
ELECTRONS
EQUILIBRIUM
EVAPORATION
ION COLLISIONS
IONIZATION
IONS
KINETIC EQUATIONS
LASER RADIATION
LAYERS
MACH NUMBER
MEAN FREE PATH
METALS
PLASMA
PLASMA SHEATH
POTENTIALS
VAPORS