Signatures of Reconnection and a Split Heliospheric Tail in High-Energy Energetic Neutral Atoms

TL;DR

This study uses advanced simulations to show that energetic neutral atom observations support a split-tail heliosphere with magnetic reconnection, challenging the traditional comet-like model.

Contribution

It demonstrates that magnetic reconnection in a split-tail heliosphere explains ENA observations, providing new insights into heliospheric structure and energetic particle sources.

Findings

ENA maps are consistent with a split-tail heliosphere.

Magnetic reconnection drives energetic particles producing ENAs.

Results challenge the traditional comet-like heliosphere model.

Abstract

The shape of the heliosphere, regarded as comet-like since the 1960s, has recently been the subject of intense debate in the last decade. There is disagreement whether the heliospheric tail extends to $\sim$10,000 au in a comet-like shape or if it is short ($\sim$400 au) with a split. Energetic neutral atom (ENA) maps from Cassini/INCA at energies from 5.2 to 13.5 keV revealed a global structure extending from the nose to the heliospheric tail known as the Belt whose origin has remained largely unexplored. Here, we use a state-of-the-art multi-ion magnetohydrodynamic (MHD) model and a novel reconnection simulation to establish that the Belt structure is consistent with a split tail heliosphere but not with a comet-like heliosphere. In a split-tail heliosphere there is a region of low-$\beta$ (ratio of thermal to magnetic pressure) in the downwind direction close to the heliopause. Direct simulations of this region reveal that magnetic reconnection is strong and drives the energetic particles that produce the >5.2keV ENAs measured by INCA in the low latitude portion of the Belt. Since the comet-like heliosphere does not produce this low-$\beta$ region and the resultant reconnection-drive mechanism for the >5.2keV ENAs, our results indicate that the INCA observations are inconsistent with a comet-like heliosphere. Further, these simulations and analysis establish for the first time that magnetic reconnection in the complex magnetic fields, expected in astrospheres across the universe, are likely to be a source of energetic particles and radiation.