The controllable super-high energetic electrons by external magnetic fields at relativistic laser-solid interactions in the presence of large scale pre-plasmas

Abstract

The two stage electron acceleration model [arXiv: 1512.02411 and arXiv: 1512.07546] is extended to the study of laser magnetized-plasmas interactions at relativistic intensities and in the presence of large-scale preformed plasmas. It is shown that the cut-off electron kinetic energy is controllable by the external magnetic field strength and directions. Further studies indicate that for a right-hand circularly polarized laser (RH-CP) of intensity 1020\ W/cm2 and pre-plasma scale length 10\ μm, the cut-off electron kinetic energy can be as high as 500\ MeV, when a homogeneous external magnetic field of exceeding 10000\ T (or B=ωc/ω0>1) is loaded along the laser propagation direction, which is a significant increase compared with that 120\ MeV without external magnetic field. A laser front sharpening mechanism is identified at relativistic laser magnetized-plasmas interactions with B=ωc/ω0>1, which is responsible for these super-high energetic electrons.