Abstract
Context. A solar-type system starts from an initial molecular core that acquires organic complexity as it evolves. The so-called prestellar cores that can be studied are rare, which has hampered our understanding of how organic chemistry sets in and grows. Aims. We selected the best prestellar core targets from the cold core catalogue (based on Planck and Herschel observations) that represent a diversity in terms of their environment to explore their chemical complexity: 1390 (in the compressed shell of Lambda Ori), 869 (in the MBM12 cloud), and 4149 (in the California nebula). Methods. We obtained a spectral survey with the IRAM 30 m telescope in order to explore the molecular complexity of the cores. We carried out a radiative transfer analysis of the detected transitions in order to place some constraints on the physical conditions of the cores and on the molecular column densities. We also used the molecular ions in the survey to estimate the cosmic-ray ionisation rate and the S/H initial elemental abundance using a gas-phase chemical model to reproduce their abundances. Results. We found large differences in the molecular complexity (deuteration, complex organic molecules, sulphur, carbon chains, and ions) and compared their chemical properties with a cold core and two prestellar cores. The chemical diversity we found in the three cores seems to be correlated with their chemical evolution: two of them are prestellar (1390 and 4149), and one is in an earlier stage (869). Conclusions. The influence of the environment is likely limited because cold cores are strongly shielded from their surroundings. The high extinction prevents interstellar UV radiation from penetrating deeply into the cores. Higher spatial resolution observations of the cores are therefore needed to constrain the physical structure of the cores, as well as a larger-scale distribution of molecular ions to understand the influence of the environment on their molecular complexity.
Highlights
Observations of molecular complexity in cold cores have long been limited by the sensitivity of the instruments
It is still not possible to explore the molecular complexity in interstellar ices, which might only be possible when the James Webb Space Telescope (JWST) becomes operational, but it is possible to detect the gas-phase emission of interstellar complex organic molecules (iCOMs) in the earliest phases of star-forming regions
These observations are crucial for understanding when and where molecular complexity is initiated in the interstellar medium (ISM) prior to delivery to a planetary system such as our own Solar System
Summary
Observations of molecular complexity in cold cores have long been limited by the sensitivity of the instruments. It is still not possible to explore the molecular complexity in interstellar ices, which might only be possible when the James Webb Space Telescope (JWST) becomes operational, but it is possible to detect the gas-phase emission of iCOMs in the earliest phases of star-forming regions. Cernicharo et al (2012) observed the methoxy radical (CH3O) towards Barnard 1 as well as methyl mercaptan (CH3SH), propynal (HCCCHO), acetaldehyde (CH3CHO), and dimethyl ether (CH3OCH3) These observations suggested that these species are formed on the surface of dust grains and are ejected to the gas phase through non-thermal desorption processes, most likely cosmic rays, which are expected to penetrate deep into the cloud and react with the abundant
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