STUDIES OF BREAKDOWN IN A PRESSURIZED RF CAVITY

M Bastaninejad,A Moretti,R P Johnson,C M Ankenbrandt,P M Hanlet,M Kuchnir,D M Kaplan,K Yonehara,M Alsharo'A,D Newsham,M Popovic,A A Elmustafa,C Thoma,D R Welch,D V Rose

doi:10.1142/s0217751x11053158

M Bastaninejad, A Moretti + Show 13 more

Open Access

PDF Available

https://doi.org/10.1142/s0217751x11053158

Copy DOI

Export

Save

Cite

Abstract
Highlights/Summary
Full-Text PDF
Similar Papers

Abstract

Listen

Microscopic images of the surfaces of metallic electrodes used in high-pressure gas-filled 805 MHz RF cavity experiments1 have been used to investigate the mechanism of RF breakdown.2 The images show evidence for melting and boiling in small regions of ~10 micron diameter on tungsten, molybdenum, and beryllium electrode surfaces. In these experiments, the dense hydrogen gas in the cavity prevents electrons or ions from being accelerated to high enough energy to participate in the breakdown process so that the only important variables are the fields and the metallic surfaces. The distributions of breakdown remnants on the electrode surfaces are compared to the maximum surface gradient E predicted by an ANSYS model of the cavity. The local surface density of spark remnants, proportional to the probability of breakdown, shows a strong exponential dependence on the maximum gradient, which is reminiscent of Fowler-Nordheim behavior of electron emission from a cold cathode. New simulation results have shown good agreement with the breakdown behavior of the hydrogen gas in the Paschen region and have suggested improved behavior with the addition of trace dopants such as SF 6.3 Present efforts are to extend the computer model to include electrode breakdown phenomena and to use scanning tunneling microscopy to search for work function differences between the conditioned and unconditioned parts of the electrodes.

Highlights

RF cavities pressurized with hydrogen gas are being developed to produce low emittance, high intensity muon beams for muon colliders, neutrino factories, and other applications
Least squares fits of the data to a power of the predicted maximum electric gradient at the surfaces of the electrodes show good agreement for high values of the exponent
Tungsten breakdown remnants are furrow-shaped melted areas extended on the surface ending in a series of overlapped circles (Figures 6, 7, 8)

Summary

Moretti

Follow this and additional works at: https://digitalcommons.odu.edu/mae_fac_pubs Part of the Engineering Physics Commons, and the Nuclear Commons. M.; Moretti, A.; Popovic, M.; Yonehara, K.; Kaplan, D. P.; Kuchnir, M.; Newsham, D.; Rose, D. M., Moretti, A., Popovic, M., Yonehara, K., . This conference paper is available at ODU Digital Commons: https://digitalcommons.odu.edu/mae_fac_pubs/49.

INTRODUCTION

EXPERIMENTAL RESULTS

CONCLUSIONS