Electromagnetic wave propagation in a fast pulse line ion accelerator

Reza A Behbahani; Quentin Diot; Brian Kavanagh; Natalie J Serkova; Moyed Miften; David C Westerly

doi:10.1002/mp.13875

Electromagnetic wave propagation in a fast pulse line ion accelerator

Med Phys. 2019 Dec;46(12):5714-5721. doi: 10.1002/mp.13875. Epub 2019 Nov 4.

Authors

Reza A Behbahani¹, Quentin Diot¹, Brian Kavanagh¹, Natalie J Serkova¹, Moyed Miften¹, David C Westerly¹

Affiliation

¹ Department of Radiation Oncology, University of Colorado School of Medicine, Aurora, CO, 80045, USA.

PMID: 31622500
DOI: 10.1002/mp.13875

Abstract

Purpose: The pulse line ion accelerator (PLIA) is a low-cost accelerator concept originally designed to accelerate heavy ions. Our group has been investigating the use of PLIA to accelerate light ions and believe a multi-stage PLIA could be useful for short half-life PET isotope production. The goal of this work was to develop a single prototype fast PLIA structure and demonstrate electromagnetic wave propagation using a high-voltage pulser.

Materials and methods: A 1.6 m fast PLIA structure (wave speed > 10⁷ m/s) was constructed along with a high-voltage, sinusoidal pulse generator. The latter uses capacitive voltage doubling and spark gap switching. A step-up transformer couples voltage from the pulser to the PLIA coil. Voltage measurements on the coil were made in air using a high-voltage resistive probe, while capacitive probes placed along the length of the PLIA were used to measure wave propagation with the PLIA structure filled with transformer oil.

Results: Voltage measurements acquired on the primary and secondary coils of the transformer coupler in air demonstrated a peak-to-peak voltage step-up of 4.2 relative to the pulser DC charging voltage. The maximum voltage time-rate-of-change on the PLIA coil was 0.76 × 10¹³ V/s. Capacitive probe measurements indicated voltage oscillations on the PLIA coil with half-period equal to 43 ± 0.9 ns and wave speed (with oil) of 1.2 × 10⁷ m/s. Average and peak accelerating gradients were conservatively estimated to be 0.44 and 0.60 MV/m, respectively, with a charging voltage of 55 kV. Wave propagation was demonstrated at these gradients without flashover at a vacuum pressure of 9 × 10^-6 Torr. Submerging the pulser in oil would allow for charging voltages up to 150 kV and produce accelerating gradients >1.2 MV/m.

Conclusions: Use of a multi-stage, fast PLIA for light ion acceleration could provide a low-cost complement to cyclotrons for the production of short half-life isotopes used for PET imaging, including carbon-11, nitrogen-13, oxygen-15, and fluorine-18.

Keywords: PET isotope production; PLIA; pulse line ion accelerator; traveling wave accelerator.

MeSH terms

Electromagnetic Phenomena*
Particle Accelerators*
Positron-Emission Tomography / instrumentation