Physical Review Special Topics. Accelerators and Beams (Apr 2008)

Modeling particle emission and power flow in pulsed-power driven, nonuniform transmission lines

  • Nichelle Bruner,
  • Thomas Genoni,
  • Elizabeth Madrid,
  • David Rose,
  • Dale Welch,
  • Kelly Hahn,
  • Joshua Leckbee,
  • Salvador Portillo,
  • Bryan Oliver,
  • Vernon Bailey,
  • David Johnson

DOI
https://doi.org/10.1103/PhysRevSTAB.11.040401
Journal volume & issue
Vol. 11, no. 4
p. 040401

Abstract

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Pulsed-power driven x-ray radiographic systems are being developed to operate at higher power in an effort to increase source brightness and penetration power. Essential to the design of these systems is a thorough understanding of electron power flow in the transmission line that couples the pulsed-power driver to the load. In this paper, analytic theory and fully relativistic particle-in-cell simulations are used to model power flow in several experimental transmission-line geometries fielded on Sandia National Laboratories’ upgraded Radiographic Integrated Test Stand [IEEE Trans. Plasma Sci. 28, 1653 (2000)ITPSBD0093-381310.1109/27.901250]. Good agreement with measured electrical currents is demonstrated on a shot-by-shot basis for simulations which include detailed models accounting for space-charge-limited electron emission, surface heating, and stimulated particle emission. Resonant cavity modes related to the transmission-line impedance transitions are also shown to be excited by electron power flow. These modes can drive oscillations in the output power of the system, degrading radiographic resolution.