Title :
Macroscopic Description of a Discharge Current in a Capillary Discharge System
Author :
Uhm, H.S. ; Kim, M.S. ; Nam, I.H. ; Lee, I.W. ; Oh, S.Y. ; Suk, H.
Author_Institution :
APRI, Gwangju Inst. of Sci. & Technol. (GIST), Gwangju, South Korea
Abstract :
Based on a simple circuit model, the global properties of the electrical discharge in a capillary discharge system are investigated by analyzing the breakdown electron temperature in terms of the applied voltage. The electrical charge and current flowing through the capillary hole are calculated from a theoretical model and compared with experimental observations, providing valuable information pertaining to system inductance, discharge-plasma resistivity in terms of the applied voltage, the breakdown temperature of electrons, and the time-averaged plasma density. The response time of the electrical breakdown in the capillary hole is expressed in terms of the electron temperature and the applied voltage.
Keywords :
discharges (electric); electric current; equivalent circuits; plasma density; plasma temperature; plasma transport processes; applied voltage; breakdown electron temperature; capillary discharge system; capillary hole; discharge current macroscopic description; discharge plasma resistivity; electrical breakdown response time; electrical discharge global properties; electron breakdown temperature; simple circuit model; system inductance; time averaged plasma density; Damping; Discharges; Inductance; Plasma accelerators; Plasma temperature; Temperature measurement; Capillary plasma; laser-driven plasma accelerator; miniature plasma; plasma jet;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2010.2079335
