Title :
Electrical discharge initiation and a macroscopic model for formative time lags
Author :
Maier, William B., II ; Kadish, A. ; Buchenauer, C. Jerald ; Robiscoe, R.T.
Author_Institution :
Los Alamos Nat. Lab., NM, USA
fDate :
12/1/1993 12:00:00 AM
Abstract :
Formative times in electrical discharges in overvoltaged gaps are analyzed with a model having no spatial dependence and with simple assumptions about discharge channel temperature T and discharge voltage. The model treats the early temporal evolution of the discharge. Specifically, the dissipative voltage drop, V*, across the discharge is taken to be a step function of T. Thermal quasi-equilibrium is assumed in the discharge medium, and it is shown that d(In td)/d(In θ)=-1, i.e., θtd=constant, where θ is the fractional overvoltage and td is the formative time lag, in agreement with measured values of td for much of the experimentally explored range of θ. Highly-time-resolved (~92 ps) experimental data are presented for the first 10 ns of electrical discharge initiation; these data suggest that the authors´ model should provide a reasonable representation of t d when td>10-100 ns
Keywords :
discharges (electric); plasma production; 10 to 100 ns; 92 ps; discharge channel temperature; discharge voltage; dissipative voltage drop; electrical discharge initiation; formative time lag; formative time lags; fractional overvoltage; highly time-resolved data; macroscopic model; overvoltaged gaps; spatial dependence; step function; thermal quasi-equilibrium; Breakdown voltage; Broadcasting; Circuits; Electrodes; Electrons; Jitter; Switches; Temperature; Time measurement; Voltage control;
Journal_Title :
Plasma Science, IEEE Transactions on
