@article{
 title = {Non-thermal atmospheric pressure discharges for surface modification},
 type = {article},
 year = {2005},
 identifiers = {[object Object]},
 pages = {1-24},
 volume = {47},
 id = {f01b5c31-abed-3b8b-82d7-13cc1757b276},
 created = {2018-11-01T17:24:28.185Z},
 file_attached = {false},
 profile_id = {6c08603e-f5fc-34c8-a4d1-319cca2e54f4},
 group_id = {18670495-6d76-3294-a982-97e5d10d5ff5},
 last_modified = {2018-11-01T17:24:28.185Z},
 read = {false},
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 citation_key = {Foest2005},
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 abstract = {There has been considerable interest in non-thermal atmospheric pressure discharges over the past decade due to the increased number of industrial applications. Diverse applications demand a solid physical and chemical understanding of the operational principals of such discharges. This paper focuses on the four most important and widely used varieties of non-thermal discharges: corona, dielectric barrier, gliding arc and spark discharge. The physics of these discharges is closely related to the breakdown phenomena. The main players in electrical breakdown of gases: avalanches and streamers are also discussed in this paper. Although non-thermal atmospheric pressure discharges have been intensively studied for the past century, a clear physical picture of these discharges is yet to be obtained.},
 bibtype = {article},
 author = {Foest, R. and Kindel, E. and Ohl, A. and Stieber, M. and Weltmann, K. D.},
 journal = {Plasma Physics and Controlled Fusion},
 number = {12 B}
}

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