DocumentCode
1435241
Title
New developments in paraxial radiographic diode technology for focusing intense relativistic electron beams
Author
Birrell, Andrew R. ; Edwards, Ray D. ; Goldsack, Tim J. ; Sinclair, Mark A.
Author_Institution
Pulsed Power Group, Atomic Weapons Establ., Aldermaston, UK
Volume
28
Issue
5
fYear
2000
fDate
10/1/2000 12:00:00 AM
Firstpage
1660
Lastpage
1663
Abstract
The Pulsed Power Group at the Atomic Weapons Establishment (AWE) is interested in the generation of small, intense, multimegavolt X-ray sources for radiographic applications. For this paper, research has been carried out into electron beam transport and focusing studies on one of our single pulse forming line flash X-ray machines. Experiments were undertaken on E Minor to improve the radiographic spot size generated by our “paraxial diode”. This is a novel anode/cathode assembly designed to produce a small-diameter electron beam focused onto a high-Z target. Electrons are propagated through a gas-filled cone such that their electrostatic repulsive and magnetic attractive forces are almost cancelled. The cone´s length and gas pressure were initially optimized and then specific gas species applied to the drift cone. Helium gas improved spot size reproducibility with respect to variations in drift gas pressure when compared with dry air. The addition of a “secondary cell” to increase the neutralization of the electron beam´s self-electric forces yielded a 30% improvement in measured radiographic spot size
Keywords
bremsstrahlung; diodes; electron beam focusing; pulse generators; radiography; relativistic electron beam tubes; Blumlein pulse forming line; E Minor; He gas; Marx generator; Pulsed Power Group; UK Atomic Weapons Establishment; X-ray tube; anode/cathode assembly; drift gas pressure; electron beam transport; electron propagation; electrostatic repulsive forces; focusing; gas pressure; gas-filled cone; high-Z target; initially optimised cone length; intense relativistic electron beams; line flash X-ray machines; magnetic attractive forces; neutralization; paraxial diode; paraxial radiographic diode technology; radiographic applications; radiographic spot size; secondary cell; self-electric forces; small intense multimegavolt X-ray sources; small-diameter electron beam focusing; small-diameter electron beam propagation; spot size reproducibility; Anodes; Assembly; Atomic measurements; Cathodes; Diodes; Electron beams; Power generation; Pulse generation; Radiography; Weapons;
fLanguage
English
Journal_Title
Plasma Science, IEEE Transactions on
Publisher
ieee
ISSN
0093-3813
Type
jour
DOI
10.1109/27.901251
Filename
901251
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