Astrochemistry

Chemical Modeling Of Aminoketene, Ethanolamine, And Glycine Production In Interstellar Ices

By Keith Cowing

Status Report

astro-ph.GA

October 28, 2025

Filed under aminoketene, astro-ph.GA, astrochemistry, biochemistry, Biosignatures, complex organic molecules, ethanolamine, glycine, Interstellar, Interstellar Grains, interstellar ice, MAGICKAL, organic chemistry

Chemical Modeling Of Aminoketene, Ethanolamine, And Glycine Production In Interstellar Ices — Energy level diagram of the C + NH3 + CO reaction. The reaction proceeds from left to right. It starts with a triplet state; the intersystem crossings to the singlet states are marked with dashed arrows. S and TS stand for singlet and transition states. Red lines indicate the most probably pathway. — astro-ph.GA

Icy interstellar dust grains are a source of complex organic molecule (COM) production, although their formation mechanisms are debated.

Laboratory experiments show that atomic C deposited onto interstellar ice analogs can react with solid-phase NH₃ to form a CHNH₂ radical, a possible precursor to COMs, including aminoketene (NH₂CHCO).

We used astrochemical kinetics models to explore the role of the reaction of atomic C with NH₃ and subsequent reaction with CO in the formation of NH₂CHCO and other COMs. We applied the three-phase chemical model MAGICKAL to hot molecular core conditions from the cold-collapse through to the hot-core stage. The chemical network was extended to include NH₂CHCO and a range of associated gas-phase, grain-surface, and bulk-ice products and reactions.

We also approximated conditions in a shocked cloud, including sputtering of ice mantles. NH₂CHCO is formed on grains at low temperatures (~10 K) with a peak solid-phase abundance of ~2×10^-10 nH. Its formation is driven by nondiffusive reactions, in particular the Eley-Rideal reaction of C with surface NH₃, followed by immediate reaction with CO.

Surface hydrogenation of NH₂CHCO produces ethanolamine with a significant abundance of ~8×10^-8 nH. In the gas-phase, although ethanolamine reaches a modest abundance peak immediately following its desorption from grains under hot-core conditions, it is destroyed more rapidly due to its high proton affinity. Molecular survival is much higher in the shocked regions, where these species seem most likely to be detected.

NH₂CHCO is produced efficiently on simulated interstellar grain surfaces, acting subsequently as an important precursor to more complex organics, including ethanolamine and glycine. Ion-molecule gas-phase destruction of NH3-bearing COMs is less efficient in shocked lower-density regions, in contrast to hot cores, enhancing their abundances and lifetimes.

Sydney A. Willis (1), Serge A. Krasnokutski (2), Nathaniel J. Morin (1), Robin T. Garrod (1 and 3) ((1) Department of Chemistry, University of Virginia, Charlottesville, VA, USA, (2) Laboratory Astrophysics Group of the Max Planck Institute for Astronomy, Friedrich Schiller University Jena, Germany, (3) Department of Astronomy, University of Virginia, Charlottesville, VA, USA)

Comments: To be published in Astronomy & Astrophysics; 16 pages, 8 figures, 6 tables
Subjects: Astrophysics of Galaxies (astro-ph.GA)
Cite as: arXiv:2510.20912 [astro-ph.GA] (or arXiv:2510.20912v1 [astro-ph.GA] for this version)
https://doi.org/10.48550/arXiv.2510.20912
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Submission history
From: Sydney Willis
[v1] Thu, 23 Oct 2025 18:07:26 UTC (1,144 KB)
https://arxiv.org/abs/2510.20912

Astrobiology, Astrochemistry,

Keith Cowing

Explorers Club Fellow, ex-NASA Space Station Payload manager/space biologist, Away Teams, Journalist, Lapsed climber, Synaesthete, Na’Vi-Jedi-Freman-Buddhist-mix, ASL, Devon Island and Everest Base Camp veteran, (he/him) 🖖🏻

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