Title :
Compact, Nanosecond, High Repetition Rate, Pulse Generator for Bioelectric Studies
Author :
Sun, Y. ; Xiao, S. ; White, J.A. ; Kolb, J.F. ; Stacey, M. ; Schoenbach, K.H.
Author_Institution :
Old Dominion Univ., Norfolk
Abstract :
The high dielectric strength and high permittivity of water allow for its use for energy storage and switching in compact pulse power systems. A 10-Omega pulse generator with flowing water as dielectric and as the switching medium is presented here. It can provide a 10-ns pulse with a risetime of approximately 2 ns and an amplitude of up to 35 kV into a matched load. The system was operated in burst mode with repetition rates of up to 400 Hz, limited by the charging power supply. For a switch with two pin electrodes, strong electrode erosion limits the use of the pulser to less than 1,000 pulses before electrode readjustment is necessary. A considerable reduction of the erosion effect on breakdown voltage was obtained with coaxial electrodes. The pulse generator was used to study the effect of the repetition rate (or the time between successive pulses) on the viability of B16 murine melanoma cells.
Keywords :
bioelectric phenomena; biomedical electrodes; biomedical electronics; cellular biophysics; electric breakdown; pulse generators; water; B16 murine melanoma cells; bioelectric studies; breakdown voltage; coaxial electrodes; compact pulse generator; compact pulse power systems; electrode erosion; electrode readjustment; energy storage; erosion effect reduction; flowing water; nanosecond pulse generator; repetition rate effect; resistance 10 ohm; switching medium; time 10 ns; voltage 35 kV; Bioelectric phenomena; Dielectric breakdown; Electrodes; Energy storage; Permittivity; Pulse generation; Pulse power systems; Pulsed power supplies; Switches; Water storage;
Journal_Title :
Dielectrics and Electrical Insulation, IEEE Transactions on
DOI :
10.1109/TDEI.2007.4286517
