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Effective versus ion thermal temperatures in the Weizmann Ne Z-pinch: Modeling and stagnation physics

Journal Article · · Physics of Plasmas
DOI:https://doi.org/10.1063/1.4865223· OSTI ID:22252013
; ; ; ; ;  [1]; ; ; ; ; ; ;  [2];  [3];  [4];  [5]
  1. Plasma Physics Division, Naval Research Laboratory, Washington, DC 20375 (United States)
  2. Weizmann Institute of Science, Rehovot 76100 (Israel)
  3. Consultant to NRL through Engility Corp., Chantilly, Virginia 20151 (United States)
  4. Falculty of Physics, Technion-Israeli Institute of Technology, Haifa (Israel)
  5. National Security Technologies, LLC, Las Vegas, Nevada 89144 (United States)
+ Show Author Affiliations

The difference between the ion thermal and effective temperatures is investigated through simulations of the Ne gas puff z-pinch reported by Kroupp et al. [Phys. Rev. Lett. 107, 105001 (2011)]. Calculations are performed using a 2D, radiation-magnetohydrodynamic code with Tabular Collisional-Radiative Equilibrium, namely Mach2-TCRE [Thornhill et al., Phys. Plasmas 8, 3480 (2001)]. The extensive data set of imaging and K-shell spectroscopy from the experiments provides a challenging validation test for z-pinch simulations. Synthetic visible images of the implosion phase match the observed large scale structure if the breakdown occurs at the density corresponding to the Paschen minimum. At the beginning of stagnation (−4 ns), computed plasma conditions change rapidly showing a rising electron density and a peak in the ion thermal temperature of ∼1.8 keV. This is larger than the ion thermal temperature (<400 eV) inferred from the experiment. By the time of peak K-shell power (0 ns), the calculated electron density is similar to the data and the electron and ion thermal temperatures are equilibrated, as is observed. Effective ion temperatures are obtained from calculated emission line widths accounting for thermal broadening and Doppler velocity shifts. The observed, large effective ion temperatures (∼4 keV) early in the stagnation of this Ne pinch can be explained solely as a combination of compressional ion heating and steep radial velocity gradients near the axis. Approximations in the modeling are discussed in regard to the higher ion thermal temperature and lower electron density early in the stagnation compared to the experimental results.

OSTI ID:
22252013
Journal Information:
Physics of Plasmas, Journal Name: Physics of Plasmas Journal Issue: 3 Vol. 21; ISSN PHPAEN; ISSN 1070-664X
Country of Publication:
United States
Language:
English

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Related Subjects

70 PLASMA PHYSICS AND FUSION TECHNOLOGY
APPROXIMATIONS
BREAKDOWN
ELECTRON DENSITY
ELECTRONS
EMISSION
IMPLOSIONS
ION TEMPERATURE
K SHELL
LINE WIDTHS
PASCHEN LAW
PEAKS
PLASMA
RADIAL VELOCITY
SIMULATION
SPECTROSCOPY
STAGNATION