Title :
Development of a Compact Radiography Accelerator Using Dielectric Wall Accelerator Technology
Author :
Sampayan, S. ; Caporaso, G. ; Chen, Y.-J. ; Hawkins, S. ; Holmes, C. ; Krogh, M. ; McCarrick, J. ; Nelson, S. ; Nunnally, W. ; Poole, B. ; Rhodes, M. ; Sanders, D. ; Selenes, K. ; Sullivan, J. ; Wang, L. ; Watson, J.
Author_Institution :
Lawrence Livermore Nat. Lab., Livermore, CA
Abstract :
We are developing an inexpensive compact accelerator system primarily intended for pulsed radiography. Design characteristics are an 8 MeV endpoint energy, 2 kA beam current, a cell gradient of approximately 3 MV/m (for an overall accelerator length is 2-3 m), and <$1/Volt capital costs. Such designs have been made possible with the development of high specific energy dielectrics (>10J/cm3), specialized transmission line designs and multi-gap laser triggered low jitter (<1 ns) gas switches. In this geometry, the pulse forming lines, switches, and insulator/beam pipe are fully integrated within each cell to form a compact, stand-alone, stackable unit. We detail our research and modeling to date, recent high voltage test results, and the integration concept of the cells into a radiographic system.
Keywords :
beam handling equipment; particle accelerator accessories; radiography; switches; compact radiography accelerator; dielectric wall accelerator technology; high specific energy dielectrics; insulator/beam pipe; pulse forming lines; pulsed radiography; switches; transmission line designs; Costs; Dielectrics; Gas lasers; Jitter; Laser modes; Optical design; Particle beams; Radiography; Switches; Transmission lines;
Conference_Titel :
Pulsed Power Conference, 2005 IEEE
Conference_Location :
Monterey, CA
Print_ISBN :
0-7803-9189-6
Electronic_ISBN :
0-7803-9190-x
DOI :
10.1109/PPC.2005.300488
