DocumentCode
3221773
Title
Power nanosecond semiconductor opening plasma switches
Author
Brylevsky, V.I. ; Efanov, V.M. ; Kardo-Sysyev, A.F. ; Tchashnicov, I.G.
Author_Institution
A.F. Ioffe Physicotech. Inst., Acad. of Sci., St. Petersburg, Russia
fYear
1996
fDate
25-27 Jun 1996
Firstpage
51
Lastpage
54
Abstract
Opening switches (OS) with inductive storage system are very promising in pulsed power applications. The density of energy stored in an inductor is higher than in a capacitor. The pulsed voltage generated during a short time at the load may be many times (dozens) higher than the voltage at which the energy has been stored. In the early 1980s a new effect of super fast voltage restoration in high voltage silicon p-n junctions, when the junction current is switched from forward to reverse direction, was discovered. This discovery gave rise to a new generation of solid state plasma opening switches, called drift step recovery diodes (DSRD). Being semiconductor devices, DSRD have unlimited life time, low jitter. A maximum repetition rate is limited mainly by heat and may be as high as megahertz. In this work the performance of DSRD and their limits are considered
Keywords
inductive energy storage; p-n junctions; plasma devices; plasma switches; pulsed power switches; drift step recovery diodes; forward direction; high voltage silicon p-n junctions; inductive storage system; inductor; junction current switching; low jitter; maximum repetition rate limit; pulsed power applications; pulsed voltage; reverse direction; semiconductor opening plasma switches; stored energy density; super fast voltage restoration; unlimited life time; Capacitors; Inductors; P-n junctions; Plasma applications; Plasma density; Power semiconductor switches; Pulse generation; Silicon; Solid state circuits; Voltage;
fLanguage
English
Publisher
ieee
Conference_Titel
Power Modulator Symposium, 1996., Twenty-Second International
Conference_Location
Boca Raton, FL
Print_ISBN
0-7803-3076-5
Type
conf
DOI
10.1109/MODSYM.1996.564448
Filename
564448
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