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1. Survey of complex organic molecules in starless and pre-stellar cores in the Perseus molecular cloud

   https://doi.org/10.1093/mnras/stae2017  

   Scibelli, Samantha; Shirley, Yancy; Megías, Andrés; Jiménez-Serra, Izaskun (September 2024, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT Cold ($$\sim$$10 K) and dense ($$\sim 10^{5}$$ cm$$^{-3}$$) cores of gas and dust within molecular clouds, known as starless and dynamically evolved pre-stellar cores, are the birthplaces of low-mass (M$$\le$$ few M$$_\odot$$) stars. As detections of interstellar complex organic molecules, or COMs, in starless cores has increased, abundance comparisons suggest that some COMs might be seeded early in the star formation process and inherited to later stages (i.e. protostellar discs and eventually comets). To date observations of COMs in starless cores have been limited, with most detections reported solely in the Taurus molecular cloud. It is therefore still a question whether different environments affect abundances. We have surveyed 35 starless and pre-stellar cores in the Perseus molecular cloud with the Arizona Radio Observatory (ARO) 12 m telescope detecting both methanol, CH$$_3$$OH, and acetaldehyde, CH$$_3$$CHO, in 100 per cent and 49 per cent of the sample, respectively. In the sub-sample of 15 cores where CH$$_3$$CHO was detected at $$\gt 3\sigma$$ ($$\sim$$18 mK) with the ARO 12 m, follow-up observations with the Yebes 40 m telescope were carried out. Detections of formic acid, t-HCOOH, ketene, H$$_2$$CCO, methyl cyanide, CH$$_3$$CN, vinyl cyanide, CH$$_2$$CHCN, methyl formate, HCOOCH$$_3$$, and dimethyl ether, CH$$_3$$OCH$$_3$$, are seen in at least 20 per cent of the cores. We discuss detection statistics, calculate column densities, and compare abundances across various stages of low-mass star formation. Our findings have more than doubled COM detection statistics in cold cores and show COMs are prevalent in the gas before star and planet formation in the Perseus molecular cloud. 

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2. A survey of CH2DOH towards starless and pre-stellar cores in the Taurus molecular cloud

   https://doi.org/10.1093/mnras/staa3649  

   Ambrose, Hannah E; Shirley, Yancy L; Scibelli, Samantha (December 2020, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT Recent observations indicate that organic molecules are prevalent towards starless and pre-stellar cores. Deuteration of these molecules has not been well studied during the starless phase. Published observations of singly deuterated methanol, CH2DOH, have only been observed in a couple of well-studied, dense, and evolved pre-stellar cores (e.g. L1544, L183). Since the formation of gas-phase methanol during this cold phase is believed to occur via desorption from the icy grain surfaces, observations of CH2DOH may be useful as a probe of the deuterium fraction in the ice mantles of dust grains. We present a systematic survey of CH2DOH towards 12 starless and pre-stellar cores in the B10 region of the Taurus molecular cloud. Nine of the 12 cores are detected with [CH2DOH]/[CH3OH] ranging from <0.04 to 0.23$$^{+0.12}_{-0.06}$$ with a median value of 0.11. Sources not detected tend to have larger virial parameters and larger methanol linewidths than detected sources. The results of this survey indicate that deuterium fractionation of organic molecules, such as methanol, during the starless phase may be more easily detectable than previously thought. 

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3. On modelling cosmic ray sputtering of interstellar grain ices

   https://doi.org/10.1093/mnras/stac2507  

   Paulive, Alec; Carder, Joshua T.; Herbst, Eric (September 2022, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT In the interstellar medium (ISM), the formation of complex organic molecules (COMs) is largely facilitated by surface reactions. However, in cold dark clouds, thermal desorption of COMs is inefficient because of the lack of thermal energy to overcome binding energies to the grain surface. Non-thermal desorption methods are therefore important explanations for the gas-phase detection of many COMs that are primarily formed on grains. Here, we present a new non-thermal desorption process: cosmic ray sputtering of grain ice surfaces based on water, carbon dioxide, and a simple mixed ice. Our model applies estimated rates of sputtering to the three-phase rate equation model nautilus-1.1, where this inclusion results in enhanced gas-phase abundances for molecules produced by grain reactions such as methanol (CH3OH) and methyl formate (HCOOCH3). Notably, species with efficient gas-phase destruction pathways exhibit less of an increase in models with sputtering compared to other molecules. These model results suggest that sputtering is an efficient, non-specific method of non-thermal desorption that should be considered as an important factor in future chemical models. 

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4. Formation of Complex Organic Molecules in Hot Molecular Cores through Nondiffusive Grain-surface and Ice-mantle Chemistry

   https://doi.org/10.3847/1538-4365/ac3131  

   Garrod, Robin_T; Jin, Miwha; Matis, Kayla_A; Jones, Dylan; Willis, Eric_R; Herbst, Eric (February 2022, The Astrophysical Journal Supplement Series)

   Abstract A new, more comprehensive model of gas–grain chemistry in hot molecular cores is presented, in which nondiffusive reaction processes on dust-grain surfaces and in ice mantles are implemented alongside traditional diffusive surface/bulk-ice chemistry. We build on our nondiffusive treatments used for chemistry in cold sources, adopting a standard collapse/warm-up physical model for hot cores. A number of other new chemical model inputs and treatments are also explored in depth, culminating in a final model that demonstrates excellent agreement with gas-phase observational abundances for many molecules, including some (e.g., methoxymethanol) that could not be reproduced by conventional diffusive mechanisms. The observed ratios of structural isomers methyl formate, glycolaldehyde, and acetic acid are well reproduced by the models. The main temperature regimes in which various complex organic molecules (COMs) are formed are identified. Nondiffusive chemistry advances the production of many COMs to much earlier times and lower temperatures than in previous model implementations. Those species may form either as by-products of simple-ice production, or via early photochemistry within the ices while external UV photons can still penetrate. Cosmic ray-induced photochemistry is less important than in past models, although it affects some species strongly over long timescales. Another production regime occurs during the high-temperature desorption of solid water, whereby radicals trapped in the ice are released onto the grain/ice surface, where they rapidly react. Several recently proposed gas-phase COM-production mechanisms are also introduced, but they rarely dominate. New surface/ice reactions involving CH and CH₂are found to contribute substantially to the formation of certain COMs. 

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5. Re-exploring Molecular Complexity with ALMA: Insights into chemical differentiation from the molecular composition of hot cores in Sgr B2(N2)

   https://doi.org/10.1051/0004-6361/202554411  

   Belloche, A; Garrod, R T; Müller, H_S P; Morin, N J; Willis, S A; Menten, K M (June 2025, Astronomy & Astrophysics)

   Context. Hot molecular cores correspond to the phase of star formation during which many molecules, in particular complex organic molecules (COMs), thermally desorb from the surface of dust grains. Sophisticated kinetic models of interstellar chemistry describe the processes that lead to the formation and subsequent evolution of COMs in star-forming regions. Aims. Our goal is to derive the chemical composition of hot cores in order to improve our understanding of interstellar chemistry. In particular, we want to test the models by comparing their predictions to the observed composition of the gas phase of hot cores. Methods. We used the Atacama Large Millimeter/submillimeter Array (ALMA) to perform an imaging spectral line survey of the high mass star-forming region Sagittarius B2(N) at 3 mm, called Re-exploring Molecular Complexity with ALMA (ReMoCA). We modeled under the assumption of local thermodynamic equilibrium the spectra obtained with this survey toward the sources embedded in the secondary hot core Sgr B2(N2). We compared the chemical composition of these sources to that of sources from the literature and to predictions of the chemical kinetics model MAGICKAL. Results. We detected up to 58 molecules toward Sgr B2(N2)’s hot cores, including up to 24 COMs, as well as many less abundant isotopologs. The compositions of some pairs of sources are well correlated, but differences also exist, in particular for HNCO and NH₂CHO. The abundances of series of homologous molecules drop by about one order of magnitude at each further step in complexity. The nondetection of radicals yields stringent constraints on the models. The comparison to the chemical models confirms previous evidence of a high cosmic-ray ionization rate in Sgr B2(N). The comparison to sources from the literature gives a new insight into chemical differentiation. The composition of most hot cores of Sgr B2(N2) is tightly correlated to that of the hot core G31.41+0.31 and the hot corino IRAS 16293–2422 B after normalizing the abundances by classes of molecules (O-bearing, N-bearing, O+N-bearing, and S-bearing). There is no overall correlation between Sgr B2(N2) and the shocked region G+0.693−0.027 also located in Sgr B2, and even less with the cold starless core TMC-1. The class of N-bearing species reveals the largest variance among the four classes of molecules. The S-bearing class shows in contrast the smallest variance. Conclusions. These results imply that the class of N-bearing molecules reacts more sensitively to shocks, low-temperature gas phase chemistry after nonthermal desorption, or density. The overall abundance shifts observed between the N-bearing and O-bearing molecules may indicate how violently and completely the ice mantles are desorbed. 

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