Alcohols on the rocks: solid-state formation in a H3CCCH + OH cocktail under dark cloud conditions
D. Qasim, G. Fedoseev, T. Lamberts, K.-J. Chuang, J. He, S. Ioppolo,, J. K\"astner, H. Linnartz

TL;DR
This study demonstrates that alcohols and related compounds can form in interstellar ice conditions well before CO freeze-out, through radical-addition reactions involving propyne and OH, with implications for astrochemistry and origins of life.
Contribution
It provides experimental and computational evidence for the formation of alcohols and other complex molecules from simple precursors at very low temperatures in space.
Findings
Alcohols can form in H2O-rich ice phases before CO freeze-out.
Propanol and propenol isomers are produced with a 1:1 ratio.
Formation pathways suggest simultaneous presence of multiple complex molecules in space.
Abstract
A number of recent experimental studies have shown that solid-state complex organic molecules (COMs) can form under conditions that are relevant to the CO freeze-out stage in dense clouds. In this work, we show that alcohols can be formed well before the CO freeze-out stage (i.e., in the H2O-rich ice phase). This joint experimental and computational investigation shows that the isomers, n- and i-propanol (H3CCH2CH2OH and H3CCHOHCH3) and n- and i-propenol (H3CCHCHOH and H3CCOHCH2), can be formed in radical-addition reactions starting from propyne (H3CCCH) + OH at the low temperature of 10 K, where H3CCCH is one of the simplest representatives of stable carbon chains already identified in the interstellar medium (ISM). The resulting average abundance ratio of 1:1 for n-propanol:i-propanol is aligned with the conclusions from the computational work that the geometric orientation of…
Peer Reviews
No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.
Videos
No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.
