Deviations from the local field approximation in negative streamer heads

Negative streamer ionization fronts in nitrogen under normal conditions are investigated both in a particle model and in a fluid model in local field approximation. The parameter functions for the fluid model are derived from swarm experiments in the particle model. The front structure on the inner...

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Bibliographic Details
Published in:Journal of applied physics 2007-06, Vol.101 (12), p.123305-123305-14
Main Authors: Li, Chao, Brok, W. J. M., Ebert, Ute, van der Mullen, J. J. A. M.
Format: Article
Language:English
Subjects:
ACCURACY
APPROXIMATIONS
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
ELECTRIC FIELDS
ELECTRONS
FLUIDS
IONIZATION
MATHEMATICAL SOLUTIONS
MONTE CARLO METHOD
NITROGEN
ONE-DIMENSIONAL CALCULATIONS
PARTICLE MODELS
PLASMA
PLASMA SIMULATION
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Summary:Negative streamer ionization fronts in nitrogen under normal conditions are investigated both in a particle model and in a fluid model in local field approximation. The parameter functions for the fluid model are derived from swarm experiments in the particle model. The front structure on the inner scale is investigated in a one-dimensional setting, allowing reasonable run time and memory consumption and high numerical accuracy without introducing superparticles. If the reduced electric field immediately before the front is ⩽ 50 kV ∕ ( cm bar ) , solutions of fluid and particle model agree very well. If the field increases up to 200 kV ∕ ( cm bar ) , the solutions of particle and fluid model deviate, in particular, the ionization level behind the front becomes up to 60% higher in the particle model while the velocity is rather insensitive. Particle and fluid model deviate because electrons with high energies do not yet fully run away from the front, but are somewhat ahead. This leads to increasing ionization rates in the particle model at the very tip of the front. The energy overshoot of electrons in the leading edge of the front actually agrees quantitatively with the energy overshoot in the leading edge of an electron swarm or avalanche in the same electric field.
ISSN:0021-8979
1089-7550
DOI:10.1063/1.2748673