2D mapping of Biermann battery fields and associated density and temperature gradients in blast waves
ORAL · Invited
Abstract
The generation of magnetic fields is of interest in both astrophysics and laboratory plasma physics research. One prevalent source of magnetic field generation is the spontaneous creation of magnetic fields via the Biermann battery effect. We present high repetition rate experiments examining Biermann generated fields in laser produced plasmas over large, three-dimensional spatial regions under vacuum and in various pressures of N2 and He background gasses where laser driven Taylor-Sedov blast waves were created. Thomson scattering (TS) was utilized to obtain the electron temperature and density within the laser driven blast waves in various background gas pressures. Novel measurements of the electron temperature and density gradients were obtained via two-dimensional TS and are compared to magnetic field measurements.
*This work was supported by the National Science Foundation Graduate Research Fellowship Program under award number DGE-1650604, the National Nuclear Security Administration (NNSA) Center for Matter Under Extreme Conditions under Award Number DE-NA0003842, the Defense Threat Reduction Agency (DTRA) and Livermore National Laboratory under contract number B655224, the Department of Energy (DOE) under award numbers DE-SC0019011 and DE-FC02-07ER54918, and the Naval Information Warfare Center-Pacific (NIWC) under contract NCRADA-NIWCPacific-19-354. This research made use of PlasmaPy version 2023.1.0, a community-developed open source Python package for plasma research and education (PlasmaPy Community et al. 2023).
