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Self-consistent plasma density evolution during RF energy extraction from a microwave pulse compressor
Summary form only given. Numerical simulations of the high-pressure plasma discharge in a switch of a microwave pulse compressor resulting in extraction of the compressor output pulse were carried out. The compressor comprised a rectangular waveguide-based cavity and an H-plane waveguide tee with a...
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| creator | Shlapakovski, Anatoli Beilin, Leonid Donskoy, Moshe Krasik, Yakov E. Schamiloglu, Edl |
| description | Summary form only given. Numerical simulations of the high-pressure plasma discharge in a switch of a microwave pulse compressor resulting in extraction of the compressor output pulse were carried out. The compressor comprised a rectangular waveguide-based cavity and an H-plane waveguide tee with a shorted side arm filled with helium. For simulations, the 3-D version of the PIC code MAGIC was used; the plasma was represented by the gas conductivity model provided by MAGIC. Simulations started from the preset RF fields (corresponding to the standing wave pattern in the cavity and H-tee), seeding electrons in a volume around the E-field antinode in the tee side arm (in the center of the waveguide cross-section), and ~10 4 cm 3 plasma density (cosmic background). The plasma density is then determined self-consistently by electron ionization cross-sections and avalanche rate, which depend on the E-field that decreases with the rise of the density. It was found that the plasma extends along the E-field forming a filament whose transverse size is set by dimensions of the volume initially populated by seeding electrons. There are three stages of the plasma density evolution: first, it grows exponentially up to the value at which the E-field within the plasma region begins to decrease because of the skin-effect; then, the avalanche rate decreases but the density still rises until the RF energy begins to rapidly release from the cavity; finally, when the E-field becomes insufficient to support the avalanche, the density is saturated. The simulated peak power and waveform of output pulses showed good agreement with those obtained experimentally in the S-band compressor with laser triggering of the plasma discharge at different levels of input microwave power. The behavior of the plasma density also agrees satisfactorily with experiments. |
| doi_str_mv | 10.1109/PLASMA.2015.7179958 |
| format | conference_proceeding |
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Numerical simulations of the high-pressure plasma discharge in a switch of a microwave pulse compressor resulting in extraction of the compressor output pulse were carried out. The compressor comprised a rectangular waveguide-based cavity and an H-plane waveguide tee with a shorted side arm filled with helium. For simulations, the 3-D version of the PIC code MAGIC was used; the plasma was represented by the gas conductivity model provided by MAGIC. Simulations started from the preset RF fields (corresponding to the standing wave pattern in the cavity and H-tee), seeding electrons in a volume around the E-field antinode in the tee side arm (in the center of the waveguide cross-section), and ~10 4 cm 3 plasma density (cosmic background). The plasma density is then determined self-consistently by electron ionization cross-sections and avalanche rate, which depend on the E-field that decreases with the rise of the density. It was found that the plasma extends along the E-field forming a filament whose transverse size is set by dimensions of the volume initially populated by seeding electrons. There are three stages of the plasma density evolution: first, it grows exponentially up to the value at which the E-field within the plasma region begins to decrease because of the skin-effect; then, the avalanche rate decreases but the density still rises until the RF energy begins to rapidly release from the cavity; finally, when the E-field becomes insufficient to support the avalanche, the density is saturated. The simulated peak power and waveform of output pulses showed good agreement with those obtained experimentally in the S-band compressor with laser triggering of the plasma discharge at different levels of input microwave power. The behavior of the plasma density also agrees satisfactorily with experiments.</description><identifier>ISSN: 0730-9244</identifier><identifier>EISSN: 2576-7208</identifier><identifier>EISBN: 1479969745</identifier><identifier>EISBN: 9781479969746</identifier><identifier>DOI: 10.1109/PLASMA.2015.7179958</identifier><language>eng</language><publisher>IEEE</publisher><subject>Cavity resonators ; Discharges (electric) ; Plasma density ; Radio frequency ; Rectangular waveguides ; Solid modeling</subject><ispartof>2015 IEEE International Conference on Plasma Sciences (ICOPS), 2015, p.1-1</ispartof><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktohtml>$$Uhttps://ieeexplore.ieee.org/document/7179958$$EHTML$$P50$$Gieee$$H</linktohtml><link.rule.ids>309,310,780,784,789,790,23930,23931,25140,27925,54555,54932</link.rule.ids><linktorsrc>$$Uhttps://ieeexplore.ieee.org/document/7179958$$EView_record_in_IEEE$$FView_record_in_$$GIEEE</linktorsrc></links><search><creatorcontrib>Shlapakovski, Anatoli</creatorcontrib><creatorcontrib>Beilin, Leonid</creatorcontrib><creatorcontrib>Donskoy, Moshe</creatorcontrib><creatorcontrib>Krasik, Yakov E.</creatorcontrib><creatorcontrib>Schamiloglu, Edl</creatorcontrib><title>Self-consistent plasma density evolution during RF energy extraction from a microwave pulse compressor</title><title>2015 IEEE International Conference on Plasma Sciences (ICOPS)</title><addtitle>PLASMA</addtitle><description>Summary form only given. Numerical simulations of the high-pressure plasma discharge in a switch of a microwave pulse compressor resulting in extraction of the compressor output pulse were carried out. The compressor comprised a rectangular waveguide-based cavity and an H-plane waveguide tee with a shorted side arm filled with helium. For simulations, the 3-D version of the PIC code MAGIC was used; the plasma was represented by the gas conductivity model provided by MAGIC. Simulations started from the preset RF fields (corresponding to the standing wave pattern in the cavity and H-tee), seeding electrons in a volume around the E-field antinode in the tee side arm (in the center of the waveguide cross-section), and ~10 4 cm 3 plasma density (cosmic background). The plasma density is then determined self-consistently by electron ionization cross-sections and avalanche rate, which depend on the E-field that decreases with the rise of the density. It was found that the plasma extends along the E-field forming a filament whose transverse size is set by dimensions of the volume initially populated by seeding electrons. There are three stages of the plasma density evolution: first, it grows exponentially up to the value at which the E-field within the plasma region begins to decrease because of the skin-effect; then, the avalanche rate decreases but the density still rises until the RF energy begins to rapidly release from the cavity; finally, when the E-field becomes insufficient to support the avalanche, the density is saturated. The simulated peak power and waveform of output pulses showed good agreement with those obtained experimentally in the S-band compressor with laser triggering of the plasma discharge at different levels of input microwave power. The behavior of the plasma density also agrees satisfactorily with experiments.</description><subject>Cavity resonators</subject><subject>Discharges (electric)</subject><subject>Plasma density</subject><subject>Radio frequency</subject><subject>Rectangular waveguides</subject><subject>Solid modeling</subject><issn>0730-9244</issn><issn>2576-7208</issn><isbn>1479969745</isbn><isbn>9781479969746</isbn><fulltext>true</fulltext><rsrctype>conference_proceeding</rsrctype><creationdate>2015</creationdate><recordtype>conference_proceeding</recordtype><sourceid>6IE</sourceid><recordid>eNotkFFPwyAcxNFo4jb9BHvhC3RCgQKPzeLUZEbj9r5Q-mfBtKWBdrpvb6N7usv9LvdwCC0pWVFK9OPHtty9laucULGSVGot1BWaUz65QksurtEsF7LIZE7UDZoRyUimc87v0DylL0JyNhVnyO2gcZkNXfJpgG7AfWNSa3ANUzKcMZxCMw4-dLgeo--O-HODoYN4nNDPEI39Yy6GFhvcehvDtzkB7scmAbah7SOkFOI9unVmih4uukD7zdN-_ZJt359f1-U284KpjHJXkMrSQgGVhTQu1yBr6wirlapoJQknxlaiMEJbKgwB4KIW0lkmrLGKLdDyf9YDwKGPvjXxfLjcw34BxRpa3Q</recordid><startdate>201505</startdate><enddate>201505</enddate><creator>Shlapakovski, Anatoli</creator><creator>Beilin, Leonid</creator><creator>Donskoy, Moshe</creator><creator>Krasik, Yakov E.</creator><creator>Schamiloglu, Edl</creator><general>IEEE</general><scope>6IE</scope><scope>6IH</scope><scope>CBEJK</scope><scope>RIE</scope><scope>RIO</scope></search><sort><creationdate>201505</creationdate><title>Self-consistent plasma density evolution during RF energy extraction from a microwave pulse compressor</title><author>Shlapakovski, Anatoli ; Beilin, Leonid ; Donskoy, Moshe ; Krasik, Yakov E. ; Schamiloglu, Edl</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-i538-14f60bc168e1767af29e7dcf03d88b1b7040acb56a59c15a0ee45d57fc35cac83</frbrgroupid><rsrctype>conference_proceedings</rsrctype><prefilter>conference_proceedings</prefilter><language>eng</language><creationdate>2015</creationdate><topic>Cavity resonators</topic><topic>Discharges (electric)</topic><topic>Plasma density</topic><topic>Radio frequency</topic><topic>Rectangular waveguides</topic><topic>Solid modeling</topic><toplevel>online_resources</toplevel><creatorcontrib>Shlapakovski, Anatoli</creatorcontrib><creatorcontrib>Beilin, Leonid</creatorcontrib><creatorcontrib>Donskoy, Moshe</creatorcontrib><creatorcontrib>Krasik, Yakov E.</creatorcontrib><creatorcontrib>Schamiloglu, Edl</creatorcontrib><collection>IEEE Electronic Library (IEL) Conference Proceedings</collection><collection>IEEE Proceedings Order Plan (POP) 1998-present by volume</collection><collection>IEEE Xplore All Conference Proceedings</collection><collection>IEEE Xplore (Online service)</collection><collection>IEEE Proceedings Order Plans (POP) 1998-present</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Shlapakovski, Anatoli</au><au>Beilin, Leonid</au><au>Donskoy, Moshe</au><au>Krasik, Yakov E.</au><au>Schamiloglu, Edl</au><format>book</format><genre>proceeding</genre><ristype>CONF</ristype><atitle>Self-consistent plasma density evolution during RF energy extraction from a microwave pulse compressor</atitle><btitle>2015 IEEE International Conference on Plasma Sciences (ICOPS)</btitle><stitle>PLASMA</stitle><date>2015-05</date><risdate>2015</risdate><spage>1</spage><epage>1</epage><pages>1-1</pages><issn>0730-9244</issn><eissn>2576-7208</eissn><eisbn>1479969745</eisbn><eisbn>9781479969746</eisbn><abstract>Summary form only given. Numerical simulations of the high-pressure plasma discharge in a switch of a microwave pulse compressor resulting in extraction of the compressor output pulse were carried out. The compressor comprised a rectangular waveguide-based cavity and an H-plane waveguide tee with a shorted side arm filled with helium. For simulations, the 3-D version of the PIC code MAGIC was used; the plasma was represented by the gas conductivity model provided by MAGIC. Simulations started from the preset RF fields (corresponding to the standing wave pattern in the cavity and H-tee), seeding electrons in a volume around the E-field antinode in the tee side arm (in the center of the waveguide cross-section), and ~10 4 cm 3 plasma density (cosmic background). The plasma density is then determined self-consistently by electron ionization cross-sections and avalanche rate, which depend on the E-field that decreases with the rise of the density. It was found that the plasma extends along the E-field forming a filament whose transverse size is set by dimensions of the volume initially populated by seeding electrons. There are three stages of the plasma density evolution: first, it grows exponentially up to the value at which the E-field within the plasma region begins to decrease because of the skin-effect; then, the avalanche rate decreases but the density still rises until the RF energy begins to rapidly release from the cavity; finally, when the E-field becomes insufficient to support the avalanche, the density is saturated. The simulated peak power and waveform of output pulses showed good agreement with those obtained experimentally in the S-band compressor with laser triggering of the plasma discharge at different levels of input microwave power. The behavior of the plasma density also agrees satisfactorily with experiments.</abstract><pub>IEEE</pub><doi>10.1109/PLASMA.2015.7179958</doi><tpages>1</tpages></addata></record> |
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| identifier | ISSN: 0730-9244 |
| ispartof | 2015 IEEE International Conference on Plasma Sciences (ICOPS), 2015, p.1-1 |
| issn | 0730-9244 2576-7208 |
| language | eng |
| recordid | cdi_ieee_primary_7179958 |
| source | IEEE Xplore All Conference Series |
| subjects | Cavity resonators Discharges (electric) Plasma density Radio frequency Rectangular waveguides Solid modeling |
| title | Self-consistent plasma density evolution during RF energy extraction from a microwave pulse compressor |
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