Dynamical Evolution of Sodium Anysotropies in the Exosphere of Mercury

TL;DR

This study investigates the short-term variability and underlying mechanisms of sodium emissions in Mercury's exosphere, revealing the influence of magnetic reconnection, photon-stimulated desorption, and sodium migration.

Contribution

It provides new high-resolution observations and analysis of sodium exosphere dynamics, linking plasma interactions and surface processes to observed asymmetries and temporal changes.

Findings

Sodium emission asymmetries are linked to plasma and photon impacts.

Magnetic reconnection regimes influence sodium variability.

Photon-stimulated desorption and sodium migration drive exospheric evolution.

Abstract

The exosphere, the tenuous collisionless cloud of gas surrounding Mercury is still a poorly known object because it is the result of many various interactions between the surface, the interplanetary medium (Solar wind, photons and meteoroids), the planetary and the interplanetary magnetic fields. Many ground-based observations have allowed the detection of intense and variable sodium emissions at global and local spatial scales, the latter being mostly concentrated in the polarmid latitude regions. These regions are indeed the preferred location of solar wind precipitation on the surface of the planet. In the present paper, by using high resolution Na observations obtained at the Canary Islands with the THEMIS solar telescope, we analyze the variability of the sodium exosphere on time-scale of 1 hour and investigate the possible mechanisms that could explain the exospheric sodium emission distribution and its dynamics. Our interpretation relates the observed sodium asymmetries to the combined effects of plasma and photons impacts onto the Mercury's surface and of sodium diffusion through the upper layer of the surface. The comparison between data and simulations seems to evidence that, similarly to what occurs at the Earth, both the magnetic reconnection regimes of pulsed or quasi-steady reconnection could occur on Mercury, and be responsible for the observed Na short term variations. In addition to this, a progressive broadening of the peak regions together with an increase of the equatorial region seem to corroborate the idea of the role of photon stimulated desorption, in association with ion sputtering and with global sodium migration around Mercury as the cause of the observed evolution of the Na exosphere.