Imaging plasma precipitation patterns at the surface of Ganymede is a key measurement for understanding the effect of Jovian plasma precipitation on the brightness and composition of the surface. Ganymede stands out as Jupiter's largest moon and also the only moon in the Solar System to feature an intrinsic magnetic field, causing the formation of a small magnetosphere inside Jupiter's much larger magnetosphere. Ganymede's magnetic field locally impedes or enhances Jovian plasma access to its surface, resulting in variable precipitation patterns (Fatemi
<p>We present plasma observations from a previously unexplored wake region of Ganymede&#8217;s magnetosphere obtained by the Jovian Auroral Distributions Experiment (JADE) onboard the Juno spacecraft as it flew by Ganymede on June 7<sup>th</sup>, 2021. This region is highlighted by 1) plasma deflection well downstream of Ganymede's magnetopause, consistent with magnetic field perturbations, 2) plasma composition that is a mix of that in Jupiter&#8217;s adjacent plasma sheet or in Ganymede's magnetosphere, and 3) proton, heavy ion and electron distributions that are compressed compared to both adjacent regions. We derive ion and electron velocity distributions, pitch angles, temperatures, and densities inthis newly explored region of Ganymede&#8217;s magnetosphere.&#160;</p>
<p>Water-group gas continuously escapes from Jupiter&#8217;s icy moon Europa in both charged and neutral states. The neutral species form co-orbiting populations of particles, or neutral toroidal clouds, eventually becoming ionized to be incorporated into the Jovian plasma environment. In September 2022, Juno performed a close flyby at ~350 km, an altitude less than the satellite&#8217;s radius, allowing it to make direct observations of water-group pickup-ions originating from the moon&#8217;s surface. These observations, along with more remote measurements by Juno of Europa-genic water-group pickup ions, provide critical constraints on the evolution and loss processes of Europa&#8217;s icy surface. We will present direct observations of water-group pickup-ions from Europa in the context of understanding the breakdown and evolution of Europa&#8217;s surface ice.</p>
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