Suppression of Electromagnetic Pulses from Laser-Target Interactions by Strong Magnetic Fields

Abstract

Laser-target interactions generate intense electromagnetic pulses (EMP) that can interfere with measurements and damage equipment. In this paper we show that applying a magnetic field to nanosecond pulse laser-target interactions decreases the magnitude of EMP. We demonstrate this effect in two experiments with different geometries (spherical vs. planar), laser intensities (1013 vs. 1015~W/cm2) and applied field strength (12~T vs. 0.1~T) that both observed suppression of EMP in the 1~GHz band (by factors of 0.65× and 0.32× respectively). We then observe the opposite effect at high intensities with a picosecond pulse: for planar experiments with laser intensities 1019~W/cm2 and magnetic fields of 6--10~T, the magnitude of EMP is increased by a factor of 1.75×. These results provide a benchmark for models of EMP generation, but suggest that magnetic fields are not a viable solution for mitigating EMP on the high intensity laser facilities where it is most damaging.