Confinement of a Z-pinch plasma with cold gas end plugs

Confinement of a Z-pinch plasma with cold gas end plugs

Plasma escaping from the ends of a Z-pinch can be slowed by a plug of cold gas. Model calculations predict that increasing the plug density will reduce the plasma motion, although experiments show that this effect is gained at the cost of greater heat loss. The helium plasma used in this work has a...

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Main Author: Milne, Andrew F.
Language:English
Published: University of British Columbia 2010
Online Access:http://hdl.handle.net/2429/24939
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spelling ndltd-UBC-oai-circle.library.ubc.ca-2429-249392018-01-05T17:42:53Z Confinement of a Z-pinch plasma with cold gas end plugs Milne, Andrew F. Plasma escaping from the ends of a Z-pinch can be slowed by a plug of cold gas. Model calculations predict that increasing the plug density will reduce the plasma motion, although experiments show that this effect is gained at the cost of greater heat loss. The helium plasma used in this work has a temperature of 35000K and a density of 8X10²² m⁻³. The measured heat flux into a helium end plug at 300K and 525 pascals is 130 MW.rn⁻². Outward motion of the plasma adds a mechanical flux of 830 MW.rn⁻². Increasing the plug density by a factor of four reduces the mechanical flux to 200 MW.rn⁻², but increases the heat flux to 420 MW.rn⁻². The corresponding heat loss to a solid electrode is approximately 400 MW.rn⁻². In terms of the total energy lost, the "wall of gas" is nearly as effective as a solid barrier. Linear systems at higher temperatures could avoid the impurities contributed by plasma/solid interaction by replacing the solid with a cold gas end plug. Science, Faculty of Physics and Astronomy, Department of Graduate 2010-05-24T02:48:25Z 2010-05-24T02:48:25Z 1984 Text Thesis/Dissertation http://hdl.handle.net/2429/24939 eng For non-commercial purposes only, such as research, private study and education. Additional conditions apply, see Terms of Use https://open.library.ubc.ca/terms_of_use. University of British Columbia
collection NDLTD
language English
sources NDLTD
description Plasma escaping from the ends of a Z-pinch can be slowed by a plug of cold gas. Model calculations predict that increasing the plug density will reduce the plasma motion, although experiments show that this effect is gained at the cost of greater heat loss. The helium plasma used in this work has a temperature of 35000K and a density of 8X10²² m⁻³. The measured heat flux into a helium end plug at 300K and 525 pascals is 130 MW.rn⁻². Outward motion of the plasma adds a mechanical flux of 830 MW.rn⁻². Increasing the plug density by a factor of four reduces the mechanical flux to 200 MW.rn⁻², but increases the heat flux to 420 MW.rn⁻². The corresponding heat loss to a solid electrode is approximately 400 MW.rn⁻². In terms of the total energy lost, the "wall of gas" is nearly as effective as a solid barrier. Linear systems at higher temperatures could avoid the impurities contributed by plasma/solid interaction by replacing the solid with a cold gas end plug. === Science, Faculty of === Physics and Astronomy, Department of === Graduate
author Milne, Andrew F.
spellingShingle Milne, Andrew F.
Confinement of a Z-pinch plasma with cold gas end plugs
author_facet Milne, Andrew F.
author_sort Milne, Andrew F.
title Confinement of a Z-pinch plasma with cold gas end plugs
title_short Confinement of a Z-pinch plasma with cold gas end plugs
title_full Confinement of a Z-pinch plasma with cold gas end plugs
title_fullStr Confinement of a Z-pinch plasma with cold gas end plugs
title_full_unstemmed Confinement of a Z-pinch plasma with cold gas end plugs
title_sort confinement of a z-pinch plasma with cold gas end plugs
publisher University of British Columbia
publishDate 2010
url http://hdl.handle.net/2429/24939
work_keys_str_mv AT milneandrewf confinementofazpinchplasmawithcoldgasendplugs
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