Interaction dust-plasma in Titan's ionosphere: feedbacks on the gas phase composition
Audrey Chatain, Nathalie Carrasco, Ludovic Vettier, Olivier, Guaitella

TL;DR
This study investigates how N2-H2 plasma species in Titan's ionosphere interact with organic aerosols, revealing chemical processes that alter gas and solid phase compositions, including the formation of HCN and CN bonds.
Contribution
It introduces the THETIS experiment to analyze plasma-aerosol interactions and provides new insights into gas phase evolution and surface chemistry effects in Titan-like conditions.
Findings
Formation of HCN, NH3-CN, and C2N2 from tholins.
Decrease in ammonia production due to radical consumption.
Surface processes weaken tholin structure and desorb small molecules.
Abstract
Titan's organic aerosols are formed in the ionosphere, a layer ionized by solar VUV photons and energetic particles from the magnetosphere of Saturn, forming a natural N2-CH4-H2 plasma. Previous works showed some chemical evolution processes: VUV photons slightly alter the aerosols nitrile bands, hydrogen atoms tend to hydrogenate their surface and carbon-containing species participate to the growth of the aerosols. This work investigates the effect of the other plasma species, namely the N2-H2 derived ions, radicals and excited states. Industrial plasmas often use N2-H2 discharges to form ammonia-based fertilizers, for metal nitriding, and to erode organic surfaces. Consequently, these are likely to affect Titan's organic aerosols. We therefore developed the THETIS experiment to study the interactions between analogues of Titan's aerosols (tholins) and the erosive N2-H2 plasma species…
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Taxonomy
TopicsAstro and Planetary Science · Laser-induced spectroscopy and plasma · Planetary Science and Exploration
