Astrochemistry

JOYS+ Analyses Of OCN−, N2O, NO, And Complex Cyanides In Ices — Thermal Processing Results In Modest Enhancement Of OCN− Ice

By Keith Cowing

Status Report

astro-ph.GA

April 30, 2026

Filed under astro-ph.GA, astrochemistry, ice, Interstellar, interstellar medium, JWST, Protoplanetary Disk, Spectroscopy

JOYS+ Analyses Of OCN−, N2O, NO, And Complex Cyanides In Ices — Thermal Processing Results In Modest Enhancement Of OCN− Ice — Our fits to the OCN− and CO absorption features toward three of the studied objects. As explained in the text, OCN− is fitted simultaneously with CO ice. The orange shaded area shows the fit to the OCN− feature. Shaded blue, green, and pink areas show the Lorentzian and Gaussian components fitted to the CO feature. The total fit is presented with solid lime green line. The black solid line shows the spline that is fitted to the bottom of the gas-phase emission or top of the gas-phase absorption lines where the data are overplotted in gray. Note that the top and bottom rows have different scales; the top row highlights the OCN− fits and the bottom row shows the CO fits. For some objects such as B1-c and IRAS 2A, where the CO feature gets saturated close to the noise level, the bottom of the CO feature is ignored when fitting the data and only the wings of the CO band, which are well above the noise level, are fitted. The fits for the other objects considered in this work are given in Figs. B.2 and B.3. — astro-ph.GA

Nitrogen-bearing molecules are more difficult to observe than oxygen-bearing ones, mainly due to the lower abundance of nitrogen in the interstellar medium.

Therefore, the formation pathways of many of these species is still under debate. Studies prior to the launch of the JWST did not have the sensitivity to observe ices toward the youngest and most deeply embedded Class 0 objects.

Here we will focus on OCN⁻, CH₃CN, C₂H₅CN, NO, and N₂O in ices to better understand their formation. We use the data from the JOYS+ program to study 8 Class 0 and 11 Class I objects with JWST. We firmly detect OCN⁻ in ices for all these objects, tentatively detect CH₃CN, C₂H₅CN, and N₂O toward three sources, and find upper limits on the NO abundance in ices.

The OCN⁻−/CO₂ ratios are found to be larger by a factor of ~2-3 for the objects that have a visible CO₂ double peak (a sign of ice thermal processing) pointing to the moderate effect of temperature on OCN⁻ production. Relation of H₂O, CO₂, and OCN⁻ with AV indicates that OCN− may tentatively form at a later stage than H₂O and CO₂.

We find that the ratios of CH₃CN, C₂H₅CN, and N₂O with respect to OCN⁻ are relatively constant within one order of magnitude across our objects, likely suggesting that they have similar ice environments. The upper limit abundances of NO are ~1 order of magnitude lower than what was previously predicted in ices of a mature protoplanetary disk. This indicates that the detected gas-phase NO in that disk may be a product of another molecule (e.g. N₂O) in the ices.

We conclude that OCN⁻ can get enhanced at higher temperatures by only a factor of ~2-3 and thus OCN⁻ detection alone does not imply ice heating. Large-sample studies of OCN⁻− toward pre-stellar cores will be useful to further confirm the formation timeline of this molecule.

P. Nazari, N. Brunken, Y. Chen, K. Slavicinska, E. F. van Dishoeck, W. R. M. Rocha, A. C. A. Boogert, M. G. Navarro, V. J. M. Le Gouellec, L. Francis, Ł. Tychoniec, A. Caratti o Garatti, C. Gieser, T. P. Greene, P. J. Kavanagh

Comments: Accepted for publication in A&A, 19 pages, 14 figures
Subjects: Astrophysics of Galaxies (astro-ph.GA)
Cite as: arXiv:2604.25915 [astro-ph.GA] (or arXiv:2604.25915v1 [astro-ph.GA] for this version)
https://doi.org/10.48550/arXiv.2604.25915
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Submission history
From: Pooneh Nazari
[v1] Tue, 28 Apr 2026 17:59:07 UTC (2,865 KB)
https://arxiv.org/abs/2604.25915

Astrobiology, Astrochemistry, Astronomy,

Keith Cowing

Biologist, Explorers Club Fellow, ex-NASA Space Biologist and Payload integrator, Editor of NASAWatch.com and Astrobiology.com, Lapsed climber, Explorer, Synaesthete, Former Challenger Center board member 🖖🏻

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