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Magnetic Rayleigh-Taylor instability mitigation in large-diametergas puff Z-pinch implosions

Recently, a new approach for efficiently generating K -shell x-rays in large-diameter, long-implosion time, structured argon gas Z-pinches has been demonstrated based on a "pusher-stabilizer-radiator" model. In this paper, direct observations of the Rayleigh-Taylor instability mitigation o...

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Published in:	Physics of plasmas 2008-02, Vol.15 (2), p.022703-022703-9
Main Authors:	Qi, N., Sze, H., Failor, B. H., Banister, J., Levine, J. S., Riordan, J. C., Steen, P., Sincerny, P., Lojewski, D.
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container_title	Physics of plasmas
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creator	Qi, N. Sze, H. Failor, B. H. Banister, J. Levine, J. S. Riordan, J. C. Steen, P. Sincerny, P. Lojewski, D.
description	Recently, a new approach for efficiently generating K -shell x-rays in large-diameter, long-implosion time, structured argon gas Z-pinches has been demonstrated based on a "pusher-stabilizer-radiator" model. In this paper, direct observations of the Rayleigh-Taylor instability mitigation of a 12 - cm diameter, 200 - ns implosion time argon Z-pinch using a laser shearing interferometer (LSI) and a laser wavefront analyzer (LWA) are presented. Using a zero-dimensional snowplow model, the imploding plasma trajectories are calculated with the driver current waveforms and the initial mass distributions measured using the planar laser induced fluorescence method. From the LSI and LWA images, the plasma density and trajectory during the implosion are measured. The measured trajectory agrees with the snowplow calculations. The suppression of hydromagnetic instabilities in the "pusher-stabilizer-radiator" structured loads, leading to a high-compression ratio, high-yield Z-pinch, is discussed. For comparison, the LSI and LWA images of an alternative load (without stabilizer) show the evolution of a highly unstable Z-pinch.
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Using a zero-dimensional snowplow model, the imploding plasma trajectories are calculated with the driver current waveforms and the initial mass distributions measured using the planar laser induced fluorescence method. From the LSI and LWA images, the plasma density and trajectory during the implosion are measured. The measured trajectory agrees with the snowplow calculations. The suppression of hydromagnetic instabilities in the "pusher-stabilizer-radiator" structured loads, leading to a high-compression ratio, high-yield Z-pinch, is discussed. 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C.</au><au>Steen, P.</au><au>Sincerny, P.</au><au>Lojewski, D.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Magnetic Rayleigh-Taylor instability mitigation in large-diametergas puff Z-pinch implosions</atitle><jtitle>Physics of plasmas</jtitle><date>2008-02-26</date><risdate>2008</risdate><volume>15</volume><issue>2</issue><spage>022703</spage><epage>022703-9</epage><pages>022703-022703-9</pages><issn>1070-664X</issn><eissn>1089-7674</eissn><coden>PHPAEN</coden><abstract>Recently, a new approach for efficiently generating K -shell x-rays in large-diameter, long-implosion time, structured argon gas Z-pinches has been demonstrated based on a "pusher-stabilizer-radiator" model. In this paper, direct observations of the Rayleigh-Taylor instability mitigation of a 12 - cm diameter, 200 - ns implosion time argon Z-pinch using a laser shearing interferometer (LSI) and a laser wavefront analyzer (LWA) are presented. Using a zero-dimensional snowplow model, the imploding plasma trajectories are calculated with the driver current waveforms and the initial mass distributions measured using the planar laser induced fluorescence method. From the LSI and LWA images, the plasma density and trajectory during the implosion are measured. The measured trajectory agrees with the snowplow calculations. The suppression of hydromagnetic instabilities in the "pusher-stabilizer-radiator" structured loads, leading to a high-compression ratio, high-yield Z-pinch, is discussed. For comparison, the LSI and LWA images of an alternative load (without stabilizer) show the evolution of a highly unstable Z-pinch.</abstract><pub>American Institute of Physics</pub><doi>10.1063/1.2839346</doi></addata></record>
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title	Magnetic Rayleigh-Taylor instability mitigation in large-diametergas puff Z-pinch implosions
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