• DocumentCode
    885439
  • Title

    Interferometric measurement of physical phenomena during the implosion phase of a puff-on-puff Z-pinch load on Double-EAGLE

  • Author

    Hazelton, Robert C. ; Yadlowsky, Edward J. ; Moschella, John J. ; Carlson, E.P. ; Vidoli, C. ; Niemel, J. ; Failor, B.H. ; Coleman, P.L. ; Levine, J.S. ; Song, Y. ; Sze, H.M. ; Thornh, J.W.

  • Author_Institution
    HY-Tech Res. Corp., Radford, VA, USA
  • Volume
    31
  • Issue
    6
  • fYear
    2003
  • Firstpage
    1355
  • Lastpage
    1362
  • Abstract
    Theoretical studies have predicted that the disruptive role of the Rayleigh-Taylor (R-T) instability on the current conduction and implosion characteristics of annular Z-pinch loads will be mitigated by mass accretion if uniform fill or multiple annular shell loads are used. Holographic interferometry was used to study these physical processes during the implosion phase of puff-on-puff loads on a terawatt accelerator. Both axial (r-z) density perturbation and azimuthal (r-θ) filamentation modes of the R-T instability were observed. Significant ionization (Z≈3-10) of the inner gas puff atoms was observed below the anode grid before the outer puff had imploded to this radial position. Radiation hydrodynamic calculations indicate that photoionization by radiation from the outer current carrying shell could not account for this ionization. Current flowing on the inner gas puff could be the source of this ionization. The effect of these physical processes on the radiation yield from z-pinches warrants further investigation.
  • Keywords
    Rayleigh-Taylor instability; Z pinch; filamentation instability; holographic interferometry; phase shifting interferometry; plasma accelerators; Double-EAGLE; Rayleigh-Taylor instability; annular Z-pinch loads; axial density perturbation; azimuthal filamentation modes; disruptive role; holographic interferometry; implosion phase; interferometric measurement; mass accretion; phase-step reconstruction; photoionization; physical phenomena; puff-on-puff Z-pinch load; radiation yield; terawatt accelerator; Digital cameras; Holography; Interferometry; Ion accelerators; Ionization; Ionizing radiation; Phase measurement; Plasma applications; Plasma measurements; Plasma x-ray sources;
  • fLanguage
    English
  • Journal_Title
    Plasma Science, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0093-3813
  • Type

    jour

  • DOI
    10.1109/TPS.2003.821582
  • Filename
    1264915