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Low voltage, low energy, and repetitive (4 Hz) operation of a conventional vircator for microwave emission in the range of 4–8 GHz

Published online by Cambridge University Press:  30 August 2013

Rohit Shukla  and
Anurag Shyam
Rohit Shukla*
Affiliation:
Energetics and Electromagnetics Division, Electronics and Instrumentation Group, Bhabha Atomic Research Centre Facility, Visakhapatanam, India
Anurag Shyam
Affiliation:
Energetics and Electromagnetics Division, Electronics and Instrumentation Group, Bhabha Atomic Research Centre Facility, Visakhapatanam, India
*
Address correspondence and reprint requests to: Rohit Shukla, Energetics and Electromagnetics Division, Electronics and Instrumentation Group, Bhabha Atomic Research Centre Facility, Visakhapatanam, APIndia. E-mail: rshukla@barc.gov.in
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Abstract

In this paper, we are presenting the microwave emission results of a vircator that emits its radiation lying well-within the microwave range of electromagnetic spectrum viz 4–8 GHz and the energy needed per shot is as low as 25 Joules only. In this reported experiment, the pulse forming line is charged to a voltage of 160 kV and the measured diode voltage is 50 kV in the experiment. The primary energy is nearly 50 Joules only and hence the energy efficiency of the high voltage pulse transformer and pulse forming line combination for the given experiment is nearly 50%. The experiment is the first of its kind in establishing (experimentally) the low voltage operation of a conventional vircator, which has a planar cylindrical cathode and stainless steel mesh anode, for the microwave emission purpose. Moreover, because of the low voltage and low energy operation we could operate the whole system in repetitive mode and we could achieve as high as 4 Hz operation with this device. Interestingly, the current density of the velvet cathode used in the present experiment is nearly 300 A/cm2 in the present reported set of experiments. One interesting observation emerging out from the present experiment is that in the low voltage operation of the vircator the beam acceleration potential is relatively low and hence the axial velocities of reflexing electrons (trapped between cathode and virtual cathode) is also limited and far less than 1.8 × 108 m/s and hence with small anode cathode gaps like that of 3 mm, which is the case of present experiments, it becomes feasible to achieve radiation frequency of 4–8 GHz from the vircator.

Keywords

Compact pulsed powerHigh power microwaveParticle in cellVirtual cathodeOscillator
Type
Research Article
Information
Laser and Particle Beams , Volume 31 , Issue 4 , December 2013 , pp. 627 - 634
Copyright
Copyright © Cambridge University Press 2013 

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