Frontiers in Astronomy and Space Sciences (May 2019)

Space-Borne Electron Accelerator Design

  • John W. Lewellen,
  • Cynthia E. Buechler,
  • Bruce E. Carlsten,
  • Gregory E. Dale,
  • Michael A. Holloway,
  • Douglas E. Patrick,
  • Steven A. Storms,
  • Dinh C. Nguyen

DOI
https://doi.org/10.3389/fspas.2019.00035
Journal volume & issue
Vol. 6

Abstract

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Renewed interest in active experiments with relativistic particle beams in space has led to the development of solid-state radio-frequency (RF) linear accelerators (linac) that can deliver MeV electron beams but operate with low-voltage DC power supplies. The solid-state RF amplifiers used to drive the accelerator are known as high-electron mobility transistors (HEMTs), and at C-band (5–6 GHz) are capable of generating up to 500 watts of RF power at 10% duty factor in a small package, i.e., the size of a postage stamp. In operation, the HEMTs are powered with 50 V DC as their bias voltage; they thus can tap into the spacecraft batteries or electrical bus as the primary power source. In this paper we describe the initial testing of a compact space-borne RF accelerator consisting of individual C-band cavities, each independently powered by a gallium nitride (GaN) HEMT. We show preliminary test results that demonstrate the beam acceleration in a single C-band cavity powered by a single HEMT operating at 10% duty factor. An example of active beam experiments in space that could benefit from the HEMT-powered accelerators is the proposed Magnetosphere-Ionosphere Connection (CONNEX) experiment (Dors et al., 2017).

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