RT info:eu-repo/semantics/article T1 Impact of strong magnetization in cylindrical plasma implosions with applied B-field measured via x-ray emission spectroscopy A1 Bailly-Grandvaux, M. A1 Florido, R. A1 Walsh, C. A. A1 Beg, F. N. A1 Bradford, P. A1 Mancini, R. C. A1 McGuffey, C. A1 Suzuki-Vidal, F. A1 Vlachos, C. A1 Santos, J. J. A1 Pérez Callejo, Gabriel A1 Gigosos Pérez, Marco Antonio AB 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 D2 -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. PB American Physics Society YR 2024 FD 2024-01 LK https://uvadoc.uva.es/handle/10324/66482 UL https://uvadoc.uva.es/handle/10324/66482 LA eng NO Physical Review Research 2024, vol 6 p. L012018 NO Producción Científica DS UVaDOC RD 27-dic-2024