https://doi.org/10.1051/epjap:2000143
Modeling of back diffusion of electrons in argon
Institute of Physics, Pregrevica 118, PO Box 68, 11080 Zemun Belgrade, Yugoslavia
Corresponding author: zoran@phy.bg.ac.yu
Received:
24
January
2000
Accepted:
9
March
2000
Published online: 15 July 2000
Back-diffusion of electrons to cathode is studied by Monte Carlo
simulation for realistic argon cross sections. In particular we
study the influence of different aspects of back-diffusion
modeling with an aim to simplify the models used in modeling of
plasma displays, low pressure gas breakdown and detectors of high
energy particles. It was found that the initial electron energy
distribution is one of the critical parameters and affects the
calculated escape factors very much. The same is true for
reflection while angular distribution of initial electrons has a
very small influence on the escape factors. The model of cross
sections combined with the selection of realistic initial
conditions was shown to represent the back-diffusion in argon very
well giving good agreement with the available experimental data.
Most importantly it was found that the range of electrons
returning to the cathode exceeds by far a mean free path and that
the number of collisions that they make before returning is quite
large. Thus it was found that for a relatively high pressure of
around 10 torr the range exceeds d= 1 cm (at E/N=12
Td,
1 Td=
and therefore application of the escape
ratios below that value of p d (where p is the pressure) is
questionable, i.e. under those conditions calculations should be
performed for the actual geometry.
PACS: 52.65.Pp – Monte Carlo methods / 52.40.Hf – Plasma-wall interactions; boundary layer effects; plasma sheaths
© EDP Sciences, 2000
