Physical Review Research (Jan 2024)

Impact of strong magnetization in cylindrical plasma implosions with applied B-field measured via x-ray emission spectroscopy

  • M. Bailly-Grandvaux,
  • R. Florido,
  • C. A. Walsh,
  • G. Pérez-Callejo,
  • F. N. Beg,
  • P. Bradford,
  • M. A. Gigosos,
  • R. C. Mancini,
  • C. McGuffey,
  • F. Suzuki-Vidal,
  • C. Vlachos,
  • J. J. Santos

DOI
https://doi.org/10.1103/PhysRevResearch.6.L012018
Journal volume & issue
Vol. 6, no. 1
p. L012018

Abstract

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Magnetization is a key strategy for enhancing inertial fusion performance, though accurate characterization of magnetized dense plasmas is needed for a better comprehension of the underlying physics. Measured spectra from imploding Ar-doped D_{2}-filled cylinders at the OMEGA laser show distinctive features with and without an imposed magnetic field. A multizone spectroscopic diagnosis leads to quantitative estimates of the plasma conditions, namely revealing a 50% core temperature rise at half mass density when a 30-T seed field is applied. Concurrently, experimental spectra align well with predictions from extended-magnetohydrodynamics simulations, providing strong evidence that the attained core conditions at peak compression are consistent with the impact of a 10-kT compressed field. These results pave the way for the validation of magnetized transport models in dense plasmas and for future magnetized laser implosion experiments at a larger scale.