Self-Consistent Simulations of Plasma and Gas Dynamics in Microplasmas with Metallic and Dielectric Electrodes

The present paper discusses a self‐consistent model of plasma and gas dynamics for atmospheric microcavities in helium. A self‐consistent and time‐dependant model is described and applied with emphasis on terms involved in the close coupling among charged species, neutral species and the electric fi...

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Bibliographic Details
Published in:Plasma processes and polymers 2009-05, Vol.6 (5), p.360-369
Main Author: Jugroot, Manish
Format: Article
Language:English
Subjects:
breakdown
Charging
DC discharges
Electric fields
Electrodes
Evolution
Gas dynamics
gas heating
Mathematical models
Microcavities
microdischarges
Microplasmas
self-consistent
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Summary:The present paper discusses a self‐consistent model of plasma and gas dynamics for atmospheric microcavities in helium. A self‐consistent and time‐dependant model is described and applied with emphasis on terms involved in the close coupling among charged species, neutral species and the electric field, including space charge. The microplasmas are studied from an initial cloud until the stages of charged particle over‐amplification and breakdown in small‐spaces, where transients are particularly important. Both metallic and dielectric electrodes are compared in terms of spatial and temporal evolution of the plasma and gas dynamics. Gas heating, neutral depletion initiation and electric field reversal are observed, highlighting the close interaction between neutral gas and charged species in governing the evolution of the microplasma. Self‐consistent modelling is applied to atmospheric microcavities. The two‐dimensional time‐dependant evolutions of both the plasma and gas dynamics illustrate the coupling between the two species in the microplasma. Gas heating and depletion highlight the close interaction between gas and plasma species, through E/N effects.
ISSN:1612-8850
1612-8869
1612-8869
DOI:10.1002/ppap.200800212