High repetition rate exploration of the Biermann battery effect in laser produced plasmas over large spatial regions

• Published in: High power laser science and engineering Vol. 10
• Main Authors: Pilgram, J. J., Adams, M. B. P., Constantin, C. G., Heuer, P. V., Ghazaryan, S., Kaloyan, M., Dorst, R. S., Schaeffer, D. B., Tzeferacos, P., Niemann, C.
• Format: Journal Article
• Language: English
• Published: Cambridge, UK Cambridge University Press 01.01.2022
• Subjects: Astrophysics; Electron energy; Evolution; Experiments; Fluid flow; Laboratories; Lasers; Magnetic fields; Magnetic flux; Magnetism; Plasma; Plasmas (physics); Qualitative analysis; Repetition; Reynolds number; Thomson scattering; laser-produced plasma; Biermann battery; high repetition rate
• ISSN: 2095-4719; 2052-3289
• DOI: 10.1017/hpl.2022.2

In this paper we present a high repetition rate experimental platform for examining the spatial structure and evolution of Biermann-generated magnetic fields in laser-produced plasmas. We have extended the work of prior experiments, which spanned over millimeter scales, by spatially measuring magnetic fields in multiple planes on centimeter scales over thousands of laser shots. Measurements with magnetic flux probes show azimuthally symmetric magnetic fields that range from 60 G at 0.7 cm from the target to 7 G at 4.2 cm from the target. The expansion rate of the magnetic fields and evolution of current density structures are also mapped and examined. Electron temperature and density of the laser-produced plasma are measured with optical Thomson scattering and used to directly calculate a magnetic Reynolds number of $1.4\times {10}^4$ , confirming that magnetic advection is dominant at $\ge 1.5$ cm from the target surface. The results are compared to FLASH simulations, which show qualitative agreement with the data.