ARTEMIS observations of electrostatic shocks inside the lunar wake

TL;DR

This paper presents the first observational evidence of electrostatic shocks inside the lunar wake, confirming simulation predictions and revealing detailed particle dynamics using ARTEMIS spacecraft data.

Contribution

It provides the first direct observations of electrostatic shocks in the lunar wake, validating recent simulation results and enhancing understanding of plasma interactions around airless bodies.

Findings

Detected electrostatic solitary structures with ~2 mV/m amplitude

Observed potential increases of ~50 V causing electron heating and ion deceleration

Identified more dissipated structures with persistent electrostatic waves

Abstract

When the solar wind encounters the Moon, a plasma void forms downstream of it, known as the lunar wake. In regions where the magnetic field is quasi-parallel to the plasma-vacuum boundary normal, plasma refills the wake primarily along magnetic field lines. As faster electrons outpace slower ions, an ambipolar electric field is generated, accelerating ions and decelerating electrons. Recent particle-in-cell simulations have shown that when accelerated supersonic ion beams from opposite sides of the wake meet near the wake center, electrostatic shocks may form, decelerating ions and heating electrons into flat-top velocity distributions. Using data from the Acceleration, Reconnection, Turbulence and Electrodynamics of the Moon's Interaction with the Sun (ARTEMIS) spacecraft, we present the first observational evidence of the predicted electrostatic shocks. Near the wake center of one event, we observed an electrostatic solitary structure with an amplitude of ~2 mV/m and a spatial scale of ~50 local Debye lengths. This structure generated a potential increase of ~50 V from upstream to downstream, heating incoming electrons by ~50 eV in the parallel direction while decelerating ions by ~60 km/s leading to a density enhancement. At a second event representing a more evolved stage, we observed more dissipated structures dominated by strong electrostatic waves, with persistent potential increases driving continued field-aligned electron heating and ion deceleration. These observations confirm simulation predictions of electrostatic shock formation and the associated particle dynamics within the lunar wake, with potential applications to understanding plasma interactions around other airless celestial bodies.