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arxiv: 2210.04113 · v2 · pith:6EKHRRD7 · submitted 2022-10-08 · astro-ph.SR · astro-ph.HE· physics.plasm-ph· physics.space-ph

Multi-species Ion Acceleration in 3D Magnetic Reconnection with Hybrid-kinetic Simulations

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classification astro-ph.SR astro-ph.HEphysics.plasm-phphysics.space-ph
keywords accelerationfermimulti-speciesreconnectionfirstfluxionsmagnetic
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Magnetic reconnection drives multi-species particle acceleration broadly in space and astrophysics. We perform the first 3D hybrid simulations (fluid electrons, kinetic ions) that contain sufficient scale separation to produce nonthermal heavy-ion acceleration, with fragmented flux ropes critical for accelerating all species. We demonstrate the acceleration of all ion species (up to Fe) into power-law spectra with similar indices, by a common Fermi acceleration mechanism. The upstream ion velocities influence the first Fermi reflection for injection. The subsequent onsets of Fermi acceleration are delayed for ions with lower charge-mass ratios (Q/M), until growing flux ropes magnetize them. This leads to a species-dependent maximum energy/nucleon $\propto(Q/M)^\alpha$. These findings are consistent with in-situ observations in reconnection regions, suggesting Fermi acceleration as the dominant multi-species ion acceleration mechanism.

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