Author:
THORNHILL LINDSEY D.,DESAI PRATEEN V.
Abstract
Asymptotically matched solutions for electron and ion density,
electron and ion
velocity, and electric potential are obtained in the boundary region of
a dense
low-temperature plasma adjacent to perfectly absorbing walls – walls
that absorb,
without reflection, incident electrons and ions. Leading-order composite
solutions,
valid throughout the boundary region, are constructed from solutions in
three
subdomains distinguished by different physical length scales: the geometric
length,
the ion mean free path and the Debye length. The composite solutions are
used to
assess the impact of electron–ion recombination in the ionization
nonequilibrium
region on sheath and presheath profiles, and on quantities evaluated at
the wall.
While, at leading order, the velocity profiles throughout the boundary
region are
not influenced by recombination, the density and potential profiles are
significantly
altered when recombination is included. These results show that the region
of rapid
change in these profiles lies closer to the wall when recombination is
explicitly
included in the model. The influence of recombination on the presheath
potential,
and consequently the wall potential, is found to scale as the natural logarithm
of the
recombination length. The broadening of the density profile results in
a larger flux
of ions accelerating through the sheath and impacting on the wall. The
influence of
recombination on the ion power flux to the wall is found to scale with
the inverse
recombination length. This scaling influences the prediction of surface
erosion rates
in technological applications that utilize these plasmas.
Publisher
Cambridge University Press (CUP)
Cited by
5 articles.
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