Investigations of the magnetic structure and the decay of a plasma‐gun‐generated compact torus

The results of a series of experimental measurements of compact toroidal (CT) plasmas produced by a magnetized coaxial plasma gun injecting into a flux‐conserving metallic liner are reported. The experiments were performed on the Beta II facility at Lawrence Livermore National Laboratory. The magnet...

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Veröffentlicht in:	Phys. Fluids; (United States) 1983-07, Vol.26 (7), p.1965-1986
Hauptverfasser:	Turner, W. C., Goldenbaum, G. C., Granneman, E. H. A., Hammer, J. H., Hartman, C. W., Prono, D. S., Taska, J.
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Sprache:	eng
Schlagworte:	70 PLASMA PHYSICS AND FUSION TECHNOLOGY 700101 - Fusion Energy- Plasma Research- Confinement, Heating, & Production 700106 - Fusion Energy- Plasma Research- Plasma Production- (-1987) ANNULAR SPACE BETA II DEVICES CLOSED PLASMA DEVICES COMPACT TORUS CONFIGURATION CONSERVATION LAWS ENERGY LOSSES EQUILIBRIUM Exact sciences and technology HELICITY LOSSES Magnetic confinement and equilibrium MAGNETIC FLUX MAGNETIC MIRRORS MAGNETIZATION OPEN PLASMA DEVICES PARTICLE PROPERTIES Physics Physics of gases, plasmas and electric discharges Physics of plasmas and electric discharges PLASMA PLASMA GUNS PLASMA PRODUCTION SPACE THERMONUCLEAR DEVICES TORI TOROIDAL CONFIGURATION
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container_end_page	1986
container_issue	7
container_start_page	1965
container_title	Phys. Fluids; (United States)
container_volume	26
creator	Turner, W. C. Goldenbaum, G. C. Granneman, E. H. A. Hammer, J. H. Hartman, C. W. Prono, D. S. Taska, J.
description	The results of a series of experimental measurements of compact toroidal (CT) plasmas produced by a magnetized coaxial plasma gun injecting into a flux‐conserving metallic liner are reported. The experiments were performed on the Beta II facility at Lawrence Livermore National Laboratory. The magnetic equilibria are well described by a force‐free eigenmode structure that results from an extension of Taylor’s theory of the reversed‐field pinch. Consideration of helicity conservation during relaxation of the composite plasma‐gun flux‐conserver system to the final state equilibrium yields theoretical expressions that are compared with the experiment. In particular the CT poloidal flux (ψpol) and the overall electrical efficiency for producing the CT are predicted to be functions of the plasma gun inner‐electrode flux (ψgun) and the volt‐seconds input to the gun discharge (∫∞ 0 V d t). Away from a cutoff at too low values of ∫∞ 0 V d t or too high values, ψgun ,ψpol scales linearly with the square root of the product of ψgun and ∫∞ 0 V d t, whereas the electrical efficiency equals about 13% for ∫∞ 0 V d t/ψgun ≊10. For an electrical energy input W in =45 kJ, CT’s are produced with poloidal plus toroidal field energy up to W B =8 kJ and toroidal plasma current I tor =330 kA. The chord‐averaged plasma density is 2–4×101 4 cm− 3, and the plasma volume equals 150 liters. The radius of the flux conserver is 37.5 cm, and the axial length is 40 cm. If a bias flux ψ b is superimposed on the flux conserver, n=1 tilting is observed when ψ b /ψpol exceeds a ratio of about 0.20 to 0.25. Impurity radiation measured by a pyroelectric detector accounts for all of the plasma magnetic energy if uniform volume emission of radiation is assumed. The dominant impurities observed are carbon and oxygen. Helium‐like lines are not observed, indicating that the plasma has not ‘‘burned through’’ the low electron temperature radiation maxima. The experimentally observed decay times (defined by the e‐folding time of plasma magnetic fields) are 80 to 160 μsec—consistent with Z eff =2 and T e in the range 5–10 eV if classical resistivity is assumed. A zero‐dimensional rate equation model of impurity radiation loss gives a reasonably good account of the experimental observations and predicts that the carbon concentration must be reduced to the level of a few percent to allow burnthrough of the low‐T e carbon radiation barrier. Glow discharge cleaning of the gun electrodes and flux conserver
doi_str_mv	10.1063/1.864345
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C. ; Goldenbaum, G. C. ; Granneman, E. H. A. ; Hammer, J. H. ; Hartman, C. W. ; Prono, D. S. ; Taska, J.</creator><creatorcontrib>Turner, W. C. ; Goldenbaum, G. C. ; Granneman, E. H. A. ; Hammer, J. H. ; Hartman, C. W. ; Prono, D. S. ; Taska, J. ; Lawrence Livermore National Laboratory, University of California, Livermore, California 94550</creatorcontrib><description>The results of a series of experimental measurements of compact toroidal (CT) plasmas produced by a magnetized coaxial plasma gun injecting into a flux‐conserving metallic liner are reported. The experiments were performed on the Beta II facility at Lawrence Livermore National Laboratory. The magnetic equilibria are well described by a force‐free eigenmode structure that results from an extension of Taylor’s theory of the reversed‐field pinch. Consideration of helicity conservation during relaxation of the composite plasma‐gun flux‐conserver system to the final state equilibrium yields theoretical expressions that are compared with the experiment. In particular the CT poloidal flux (ψpol) and the overall electrical efficiency for producing the CT are predicted to be functions of the plasma gun inner‐electrode flux (ψgun) and the volt‐seconds input to the gun discharge (∫∞ 0 V d t). Away from a cutoff at too low values of ∫∞ 0 V d t or too high values, ψgun ,ψpol scales linearly with the square root of the product of ψgun and ∫∞ 0 V d t, whereas the electrical efficiency equals about 13% for ∫∞ 0 V d t/ψgun ≊10. For an electrical energy input W in =45 kJ, CT’s are produced with poloidal plus toroidal field energy up to W B =8 kJ and toroidal plasma current I tor =330 kA. The chord‐averaged plasma density is 2–4×101 4 cm− 3, and the plasma volume equals 150 liters. The radius of the flux conserver is 37.5 cm, and the axial length is 40 cm. If a bias flux ψ b is superimposed on the flux conserver, n=1 tilting is observed when ψ b /ψpol exceeds a ratio of about 0.20 to 0.25. Impurity radiation measured by a pyroelectric detector accounts for all of the plasma magnetic energy if uniform volume emission of radiation is assumed. The dominant impurities observed are carbon and oxygen. Helium‐like lines are not observed, indicating that the plasma has not ‘‘burned through’’ the low electron temperature radiation maxima. The experimentally observed decay times (defined by the e‐folding time of plasma magnetic fields) are 80 to 160 μsec—consistent with Z eff =2 and T e in the range 5–10 eV if classical resistivity is assumed. A zero‐dimensional rate equation model of impurity radiation loss gives a reasonably good account of the experimental observations and predicts that the carbon concentration must be reduced to the level of a few percent to allow burnthrough of the low‐T e carbon radiation barrier. Glow discharge cleaning of the gun electrodes and flux conserver resulted in a 20% increase of the e‐folding time of plasma magnetic fields (from an average value 115 to 140 μsec). The CT plasma density was observed to scale linearly with the electrical energy input to the gun discharge and to be only weakly dependent on the filling pressure and timing of pulsed deuterium gas valves. It seems likely that further improvements in increasing plasma lifetime can be made by improving the vacuum conditions and discharge cleaning methods and experimenting with the gun electrode materials.</description><identifier>ISSN: 0031-9171</identifier><identifier>EISSN: 2163-4998</identifier><identifier>DOI: 10.1063/1.864345</identifier><identifier>CODEN: PFLDAS</identifier><language>eng</language><publisher>Woodbury, NY: American Institute of Physics</publisher><subject>70 PLASMA PHYSICS AND FUSION TECHNOLOGY ; 700101 - Fusion Energy- Plasma Research- Confinement, Heating, & Production ; 700106 - Fusion Energy- Plasma Research- Plasma Production- (-1987) ; ANNULAR SPACE ; BETA II DEVICES ; CLOSED PLASMA DEVICES ; COMPACT TORUS ; CONFIGURATION ; CONSERVATION LAWS ; ENERGY LOSSES ; EQUILIBRIUM ; Exact sciences and technology ; HELICITY ; LOSSES ; Magnetic confinement and equilibrium ; MAGNETIC FLUX ; MAGNETIC MIRRORS ; MAGNETIZATION ; OPEN PLASMA DEVICES ; PARTICLE PROPERTIES ; Physics ; Physics of gases, plasmas and electric discharges ; Physics of plasmas and electric discharges ; PLASMA ; PLASMA GUNS ; PLASMA PRODUCTION ; SPACE ; THERMONUCLEAR DEVICES ; TORI ; TOROIDAL CONFIGURATION</subject><ispartof>Phys. Fluids; (United States), 1983-07, Vol.26 (7), p.1965-1986</ispartof><rights>American Institute of Physics</rights><rights>1984 INIST-CNRS</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c383t-49f41b0f4cf79218e230a12060a025b1c6239ca005a1558c5a6a5d2f09ffc9e03</citedby><cites>FETCH-LOGICAL-c383t-49f41b0f4cf79218e230a12060a025b1c6239ca005a1558c5a6a5d2f09ffc9e03</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,776,780,881,27901,27902</link.rule.ids><backlink>$$Uhttp://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=9310720$$DView record in Pascal Francis$$Hfree_for_read</backlink><backlink>$$Uhttps://www.osti.gov/biblio/5890562$$D View this record in Osti.gov$$Hfree_for_read</backlink></links><search><creatorcontrib>Turner, W. C.</creatorcontrib><creatorcontrib>Goldenbaum, G. C.</creatorcontrib><creatorcontrib>Granneman, E. H. A.</creatorcontrib><creatorcontrib>Hammer, J. H.</creatorcontrib><creatorcontrib>Hartman, C. W.</creatorcontrib><creatorcontrib>Prono, D. S.</creatorcontrib><creatorcontrib>Taska, J.</creatorcontrib><creatorcontrib>Lawrence Livermore National Laboratory, University of California, Livermore, California 94550</creatorcontrib><title>Investigations of the magnetic structure and the decay of a plasma‐gun‐generated compact torus</title><title>Phys. Fluids; (United States)</title><description>The results of a series of experimental measurements of compact toroidal (CT) plasmas produced by a magnetized coaxial plasma gun injecting into a flux‐conserving metallic liner are reported. The experiments were performed on the Beta II facility at Lawrence Livermore National Laboratory. The magnetic equilibria are well described by a force‐free eigenmode structure that results from an extension of Taylor’s theory of the reversed‐field pinch. Consideration of helicity conservation during relaxation of the composite plasma‐gun flux‐conserver system to the final state equilibrium yields theoretical expressions that are compared with the experiment. In particular the CT poloidal flux (ψpol) and the overall electrical efficiency for producing the CT are predicted to be functions of the plasma gun inner‐electrode flux (ψgun) and the volt‐seconds input to the gun discharge (∫∞ 0 V d t). Away from a cutoff at too low values of ∫∞ 0 V d t or too high values, ψgun ,ψpol scales linearly with the square root of the product of ψgun and ∫∞ 0 V d t, whereas the electrical efficiency equals about 13% for ∫∞ 0 V d t/ψgun ≊10. For an electrical energy input W in =45 kJ, CT’s are produced with poloidal plus toroidal field energy up to W B =8 kJ and toroidal plasma current I tor =330 kA. The chord‐averaged plasma density is 2–4×101 4 cm− 3, and the plasma volume equals 150 liters. The radius of the flux conserver is 37.5 cm, and the axial length is 40 cm. If a bias flux ψ b is superimposed on the flux conserver, n=1 tilting is observed when ψ b /ψpol exceeds a ratio of about 0.20 to 0.25. Impurity radiation measured by a pyroelectric detector accounts for all of the plasma magnetic energy if uniform volume emission of radiation is assumed. The dominant impurities observed are carbon and oxygen. Helium‐like lines are not observed, indicating that the plasma has not ‘‘burned through’’ the low electron temperature radiation maxima. The experimentally observed decay times (defined by the e‐folding time of plasma magnetic fields) are 80 to 160 μsec—consistent with Z eff =2 and T e in the range 5–10 eV if classical resistivity is assumed. A zero‐dimensional rate equation model of impurity radiation loss gives a reasonably good account of the experimental observations and predicts that the carbon concentration must be reduced to the level of a few percent to allow burnthrough of the low‐T e carbon radiation barrier. Glow discharge cleaning of the gun electrodes and flux conserver resulted in a 20% increase of the e‐folding time of plasma magnetic fields (from an average value 115 to 140 μsec). The CT plasma density was observed to scale linearly with the electrical energy input to the gun discharge and to be only weakly dependent on the filling pressure and timing of pulsed deuterium gas valves. It seems likely that further improvements in increasing plasma lifetime can be made by improving the vacuum conditions and discharge cleaning methods and experimenting with the gun electrode materials.</description><subject>70 PLASMA PHYSICS AND FUSION TECHNOLOGY</subject><subject>700101 - Fusion Energy- Plasma Research- Confinement, Heating, & Production</subject><subject>700106 - Fusion Energy- Plasma Research- Plasma Production- (-1987)</subject><subject>ANNULAR SPACE</subject><subject>BETA II DEVICES</subject><subject>CLOSED PLASMA DEVICES</subject><subject>COMPACT TORUS</subject><subject>CONFIGURATION</subject><subject>CONSERVATION LAWS</subject><subject>ENERGY LOSSES</subject><subject>EQUILIBRIUM</subject><subject>Exact sciences and technology</subject><subject>HELICITY</subject><subject>LOSSES</subject><subject>Magnetic confinement and equilibrium</subject><subject>MAGNETIC FLUX</subject><subject>MAGNETIC MIRRORS</subject><subject>MAGNETIZATION</subject><subject>OPEN PLASMA DEVICES</subject><subject>PARTICLE PROPERTIES</subject><subject>Physics</subject><subject>Physics of gases, plasmas and electric discharges</subject><subject>Physics of plasmas and electric discharges</subject><subject>PLASMA</subject><subject>PLASMA GUNS</subject><subject>PLASMA PRODUCTION</subject><subject>SPACE</subject><subject>THERMONUCLEAR DEVICES</subject><subject>TORI</subject><subject>TOROIDAL CONFIGURATION</subject><issn>0031-9171</issn><issn>2163-4998</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>1983</creationdate><recordtype>article</recordtype><recordid>eNp1kM9KAzEQxoMoWKvgIwTxoIetk2Sz3Ryl-KdQ8KLnZTpN2pU2W5Ks0JuP4DP6JHa74s3LzGF-fN98H2OXAkYCCnUnRmWRq1wfsYEUhcpyY8pjNgBQIjNiLE7ZWYzvADIXuRqw-dR_2JjqJaa68ZE3jqeV5Rtceptq4jGFllIbLEe_OJwWlnDXcci3a4wb_P78Wra-m9bbgMkuODWbLVLiqQltPGcnDtfRXvzuIXt7fHidPGezl6fp5H6WkSpV2j_qcjEHl5MbGylKKxWgkFAAgtRzQYVUhhBAo9C6JI0F6oV0YJwjY0EN2VWv2-zzVJHqZGlFjfeWUqVLA3qvMGQ3PUShiTFYV21DvcGwqwRUXYGVqPoC9-h1j24xEq5dQE91_OONEjCWne1tj3WOhxb_l_wBUxd-aA</recordid><startdate>198307</startdate><enddate>198307</enddate><creator>Turner, W. C.</creator><creator>Goldenbaum, G. C.</creator><creator>Granneman, E. H. A.</creator><creator>Hammer, J. H.</creator><creator>Hartman, C. W.</creator><creator>Prono, D. S.</creator><creator>Taska, J.</creator><general>American Institute of Physics</general><scope>IQODW</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>OTOTI</scope></search><sort><creationdate>198307</creationdate><title>Investigations of the magnetic structure and the decay of a plasma‐gun‐generated compact torus</title><author>Turner, W. C. ; Goldenbaum, G. C. ; Granneman, E. H. A. ; Hammer, J. H. ; Hartman, C. W. ; Prono, D. 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C.</creatorcontrib><creatorcontrib>Goldenbaum, G. C.</creatorcontrib><creatorcontrib>Granneman, E. H. A.</creatorcontrib><creatorcontrib>Hammer, J. H.</creatorcontrib><creatorcontrib>Hartman, C. W.</creatorcontrib><creatorcontrib>Prono, D. S.</creatorcontrib><creatorcontrib>Taska, J.</creatorcontrib><creatorcontrib>Lawrence Livermore National Laboratory, University of California, Livermore, California 94550</creatorcontrib><collection>Pascal-Francis</collection><collection>CrossRef</collection><collection>OSTI.GOV</collection><jtitle>Phys. Fluids; (United States)</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Turner, W. C.</au><au>Goldenbaum, G. C.</au><au>Granneman, E. H. A.</au><au>Hammer, J. H.</au><au>Hartman, C. W.</au><au>Prono, D. S.</au><au>Taska, J.</au><aucorp>Lawrence Livermore National Laboratory, University of California, Livermore, California 94550</aucorp><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Investigations of the magnetic structure and the decay of a plasma‐gun‐generated compact torus</atitle><jtitle>Phys. Fluids; (United States)</jtitle><date>1983-07</date><risdate>1983</risdate><volume>26</volume><issue>7</issue><spage>1965</spage><epage>1986</epage><pages>1965-1986</pages><issn>0031-9171</issn><eissn>2163-4998</eissn><coden>PFLDAS</coden><abstract>The results of a series of experimental measurements of compact toroidal (CT) plasmas produced by a magnetized coaxial plasma gun injecting into a flux‐conserving metallic liner are reported. The experiments were performed on the Beta II facility at Lawrence Livermore National Laboratory. The magnetic equilibria are well described by a force‐free eigenmode structure that results from an extension of Taylor’s theory of the reversed‐field pinch. Consideration of helicity conservation during relaxation of the composite plasma‐gun flux‐conserver system to the final state equilibrium yields theoretical expressions that are compared with the experiment. In particular the CT poloidal flux (ψpol) and the overall electrical efficiency for producing the CT are predicted to be functions of the plasma gun inner‐electrode flux (ψgun) and the volt‐seconds input to the gun discharge (∫∞ 0 V d t). Away from a cutoff at too low values of ∫∞ 0 V d t or too high values, ψgun ,ψpol scales linearly with the square root of the product of ψgun and ∫∞ 0 V d t, whereas the electrical efficiency equals about 13% for ∫∞ 0 V d t/ψgun ≊10. For an electrical energy input W in =45 kJ, CT’s are produced with poloidal plus toroidal field energy up to W B =8 kJ and toroidal plasma current I tor =330 kA. The chord‐averaged plasma density is 2–4×101 4 cm− 3, and the plasma volume equals 150 liters. The radius of the flux conserver is 37.5 cm, and the axial length is 40 cm. If a bias flux ψ b is superimposed on the flux conserver, n=1 tilting is observed when ψ b /ψpol exceeds a ratio of about 0.20 to 0.25. Impurity radiation measured by a pyroelectric detector accounts for all of the plasma magnetic energy if uniform volume emission of radiation is assumed. The dominant impurities observed are carbon and oxygen. Helium‐like lines are not observed, indicating that the plasma has not ‘‘burned through’’ the low electron temperature radiation maxima. The experimentally observed decay times (defined by the e‐folding time of plasma magnetic fields) are 80 to 160 μsec—consistent with Z eff =2 and T e in the range 5–10 eV if classical resistivity is assumed. A zero‐dimensional rate equation model of impurity radiation loss gives a reasonably good account of the experimental observations and predicts that the carbon concentration must be reduced to the level of a few percent to allow burnthrough of the low‐T e carbon radiation barrier. Glow discharge cleaning of the gun electrodes and flux conserver resulted in a 20% increase of the e‐folding time of plasma magnetic fields (from an average value 115 to 140 μsec). The CT plasma density was observed to scale linearly with the electrical energy input to the gun discharge and to be only weakly dependent on the filling pressure and timing of pulsed deuterium gas valves. It seems likely that further improvements in increasing plasma lifetime can be made by improving the vacuum conditions and discharge cleaning methods and experimenting with the gun electrode materials.</abstract><cop>Woodbury, NY</cop><pub>American Institute of Physics</pub><doi>10.1063/1.864345</doi><tpages>22</tpages></addata></record>
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subjects	70 PLASMA PHYSICS AND FUSION TECHNOLOGY 700101 - Fusion Energy- Plasma Research- Confinement, Heating, & Production 700106 - Fusion Energy- Plasma Research- Plasma Production- (-1987) ANNULAR SPACE BETA II DEVICES CLOSED PLASMA DEVICES COMPACT TORUS CONFIGURATION CONSERVATION LAWS ENERGY LOSSES EQUILIBRIUM Exact sciences and technology HELICITY LOSSES Magnetic confinement and equilibrium MAGNETIC FLUX MAGNETIC MIRRORS MAGNETIZATION OPEN PLASMA DEVICES PARTICLE PROPERTIES Physics Physics of gases, plasmas and electric discharges Physics of plasmas and electric discharges PLASMA PLASMA GUNS PLASMA PRODUCTION SPACE THERMONUCLEAR DEVICES TORI TOROIDAL CONFIGURATION
title	Investigations of the magnetic structure and the decay of a plasma‐gun‐generated compact torus
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