Physical Review Accelerators and Beams (Apr 2017)

Impedance-matched Marx generators

  • W. A. Stygar,
  • K. R. LeChien,
  • M. G. Mazarakis,
  • M. E. Savage,
  • B. S. Stoltzfus,
  • K. N. Austin,
  • E. W. Breden,
  • M. E. Cuneo,
  • B. T. Hutsel,
  • S. A. Lewis,
  • G. R. McKee,
  • J. K. Moore,
  • T. D. Mulville,
  • D. J. Muron,
  • D. B. Reisman,
  • M. E. Sceiford,
  • M. L. Wisher

DOI
https://doi.org/10.1103/PhysRevAccelBeams.20.040402
Journal volume & issue
Vol. 20, no. 4
p. 040402

Abstract

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We have conceived a new class of prime-power sources for pulsed-power accelerators: impedance-matched Marx generators (IMGs). The fundamental building block of an IMG is a brick, which consists of two capacitors connected electrically in series with a single switch. An IMG comprises a single stage or several stages distributed axially and connected in series. Each stage is powered by a single brick or several bricks distributed azimuthally within the stage and connected in parallel. The stages of a multistage IMG drive an impedance-matched coaxial transmission line with a conical center conductor. When the stages are triggered sequentially to launch a coherent traveling wave along the coaxial line, the IMG achieves electromagnetic-power amplification by triggered emission of radiation. Hence a multistage IMG is a pulsed-power analogue of a laser. To illustrate the IMG approach to prime power, we have developed conceptual designs of two ten-stage IMGs with LC time constants on the order of 100 ns. One design includes 20 bricks per stage, and delivers a peak electrical power of 1.05 TW to a matched-impedance 1.22-Ω load. The design generates 113 kV per stage and has a maximum energy efficiency of 89%. The other design includes a single brick per stage, delivers 68 GW to a matched-impedance 19-Ω load, generates 113 kV per stage, and has a maximum energy efficiency of 90%. For a given electrical-power-output time history, an IMG is less expensive and slightly more efficient than a linear transformer driver, since an IMG does not use ferromagnetic cores.