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High-fidelity modeling of breakdown in helium: initiation processes and secondary electron emission
Understanding the role of physical processes contributing to breakdown is critical for many applications in which breakdown is undesirable, such as capacitors, and applications in which controlled breakdown is intended, such as plasma medicine, lightning protection, and materials processing. The ele...
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Published in: | Journal of physics. D, Applied physics Applied physics, 2021-08, Vol.54 (33), p.334005 |
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Main Authors: | , , , , , , , , |
Format: | Article |
Language: | English |
Subjects: | |
Citations: | Items that this one cites Items that cite this one |
Online Access: | Get full text |
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Summary: | Understanding the role of physical processes contributing to breakdown is critical for many applications in which breakdown is undesirable, such as capacitors, and applications in which controlled breakdown is intended, such as plasma medicine, lightning protection, and materials processing. The electron emission from the cathode is a critical source of electrons which then undergo impact ionization to produce electrical breakdown. In this study, the role of secondary electron yields due to photons (
γ
ph
) and ions (
γ
i
) in direct current breakdown is investigated using a particle-in-cell direct simulation Monte Carlo model. The plasma studied is a one-dimensional discharge in 50 Torr of pure helium with a platinum cathode, gap size of 1.15 cm, and voltages of 1.2–1.8 kV. The current traces are compared with experimental measurements. Larger values of
γ
ph
generally result in a faster breakdown, while larger values of
γ
i
result in a larger maximum current. The 58.4 nm photons emitted from He(2
1
P) are the primary source of electrons at the cathode before the cathode fall is developed. Of the values of
γ
ph
and
γ
i
investigated, those which provide the best agreement with the experimental current measurements are
γ
ph
= 0.005 and
γ
i
= 0.01. These values are significantly lower than those in the literature for pristine platinum or for a graphitic carbon film which we speculate may cover the platinum. This difference is in part due to the limitations of a one-dimensional model but may also indicate surface conditions and exposure to a plasma can have a significant effect on the secondary electron yields. The effects of applied voltage and the current produced by a UV diode which was used to initiate the discharge, are also discussed. |
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ISSN: | 0022-3727 1361-6463 |
DOI: | 10.1088/1361-6463/ac0461 |