Solitary Magnetic Structures at Quasi-Parallel Collisionless Shocks: Formation

Solitary magnetic structures known as SLAMS (short large-amplitude magnetic structures) have been considered as essential elements of collisionless shocks with quasi-parallel geometries. Yet the physics underlying their formation remains an open question. In this paper, we use measurements from the magnetospheric multiscale mission combined with fully kinetic simulations to study the formation of SLAMS. We find that gyro-resonance between solar wind ions and right-hand circularly polarized electromagnetic waves results in magnetic field amplification. Gyro-trapping by the growing magnetic field buildup the plasma density that further enhances the current and field. The solitary nature of SLAMS stems from a beat-like magnetic field envelope where the maximum sets the initial location for nonlinear growth. Our results present a conceptual advance on SLAMS, and may shed new light on the open question of magnetic field amplification at astrophysical shocks.

Automated summary

The study investigates the formation of solitary magnetic structures known as SLAMS using measurements from the magnetospheric multiscale mission combined with fully kinetic simulations. The results indicate that gyro-resonance between solar wind ions and electromagnetic waves leads to magnetic field amplification, while the solitary nature of SLAMS is attributed to a specific magnetic field envelope.