Title :
Nanosecond pulse generators for microdischarge excimer lamps
Author :
Moselhy, Mohamed M. ; Schoenbach, Karl H.
Author_Institution :
Inst. of Phys. Electron. Res., Old Dominion Univ., Norfolk, VA, USA
Abstract :
Pulsed electron heating causes an increase in electron temperature with negligible gas heating, as long as the pulse duration is comparable to or less than the relaxation time of the electrons in the discharge plasma. For atmospheric pressure plasmas this is tens of ns. Since the sustaining voltage of microhollow cathode discharges is only 200 V, pulsed voltages of up to 1 kV are sufficient to increase the electron temperature in these plasmas considerably. A combination utilizing a MOSFET as a switch with a pulse forming network (PFN) in a Blumlein configuration has provided pulses with FWHM down to 10 ns, and rise and fall times of 4 ns. Applying these short pulses to DC microhollow cathode discharges resulted in significant increases in excimer emission, and, for xenon discharges, in excimer efficiency.
Keywords :
cathodes; discharge lamps; discharges (electric); excimers; field effect transistor switches; optimisation; plasma heating; pulse generators; xenon; 10 ns; 200 V; 4 ns; Blumlein configuration; DC microhollow cathode discharges; MOSFET switch; electron relaxation time; electron temperature; excimer emission; gas heating; microdischarge excimer lamps; nanosecond pulse generators; optimization; plasma atmospheric pressure; plasma discharge; pulse forming network; pulsed electron heating; pulsed voltages; xenon discharges; Atmospheric-pressure plasmas; Cathodes; Electrons; Heating; Lamps; MOSFET circuits; Plasma temperature; Pulse generation; Switches; Voltage;
Conference_Titel :
Pulsed Power Conference, 2003. Digest of Technical Papers. PPC-2003. 14th IEEE International
Conference_Location :
Dallas, TX, USA
Print_ISBN :
0-7803-7915-2
DOI :
10.1109/PPC.2003.1278057
