Probing non-polar interstellar molecules through their protonated form: Detection of protonated cyanogen (NCCNH<sup>+</sup>)

Agúndez, M.; Cernicharo, J.; Vicente, P. de; Marcelino, N.; Roueff, E.; Fuente, A.; Gérin, M.; Guèlin, M.; Albo, C.; Barcia, A.; Barbas, L.; Bolaño, R.; Colomer, F.; Diez, M.C.; Gallego, J. D.; Gómez-González, J.; López-Fernández, I.; López-Fernández, Jesús A.; López-Pérez, J. A.; Malo, I.; Serna, J. M.; Tercero, F.

doi:10.1051/0004-6361/201526650

Cited by 90 publications

(100 citation statements)

References 40 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…(ii) Formation (or destruction) routes for HCNH + and HC 3 NH + must be added to the chemical network. Agúndez et al (2015) also came to this conclusion in their study of the ion NCCNH + in the cold dark clouds TMC-1 and L483. In Figure 6.…”

Section: Discussionmentioning

confidence: 81%

Detection of the HC3NH+ and HCNH+ ions in the L1544 pre-stellar core

Quénard

Vastel

Ceccarelli

et al. 2017

Monthly Notices of the Royal Astronomical Society

View full text Add to dashboard Cite

The L1544 pre-stellar core was observed as part of the ASAI (Astrochemical Surveys At IRAM) Large Program. We report the first detection in a pre-stellar core of the HCNH + and HC 3 NH + ions. The high spectral resolution of the observations allows to resolve the hyperfine structure of HCNH + . Local thermodynamic equilibrium analysis leads to derive a column density equal to (2.0±0.2)×10 13 cm −2 for HCNH + and (1.5±0.5)×10 11 cm −2 for HC 3 NH + . We also present non-LTE analysis of five transitions of HC 3 N, three transitions of H 13 CN and one transition of HN 13 C, all of them linked to the chemistry of HCNH + and HC 3 NH + . We computed for HC 3 N, HCN, and HNC a column density of (2.0±0.4)×10 13 cm −2 , (3.6±0.9)×10 14 cm −2 , and (3.0±1.0)×10 14 cm −2 , respectively. We used the gas-grain chemical code Nautilus to predict the abundances all these species across the pre-stellar core. Comparison of the observations with the model predictions suggests that the emission from HCNH + and HC 3 NH + originates in the external layer where non-thermal desorption of other species was previously observed. The observed abundance of both ionic species ([HCNH + ] 3 × 10 −10 and [HC 3 NH + ] [1.5 − 3.0] × 10 −12 , with respect to H 2 ) cannot be reproduced at the same time by the chemical modelling, within the error bars of the observations only. We discuss the possible reasons for the discrepancy and suggest that the current chemical models are not fully accurate or complete. However, the modelled abundances are within a factor of three consistent with the observations, considering a late stage of the evolution of the pre-stellar core, compatible with previous observations.

show abstract

Section: Discussionmentioning

confidence: 81%

Detection of the HC3NH+ and HCNH+ ions in the L1544 pre-stellar core

Quénard

Vastel

Ceccarelli

et al. 2017

Monthly Notices of the Royal Astronomical Society

View full text Add to dashboard Cite

show abstract

“…Our analysis yielded a fractional molecular abundance of 1.4×10 −12 for this species (Table 2). If we assume a [NCCNH + ]/[NCCN] ratio of ∼10 −4 as inferred from the chemical modelling of Agúndez et al (2015), the abundance of NCCN would be 1.4×10 −8 cm −2 .…”

Section: Analysis and Resultsmentioning

confidence: 99%

Abundant Z-cyanomethanimine in the interstellar medium: paving the way to the synthesis of adenine

Rivilla

Martı́n-Pintado

Jiménez-Serra

et al. 2018

Monthly Notices of the Royal Astronomical Society: Letters

110

View full text Add to dashboard Cite

We report the first detection in the interstellar medium of the Z-isomer of cyanomethanimine (HNCHCN), an HCN dimer proposed as precursor of adenine. We identified six transitions of Z-cyanomethanimine, along with five transitions of Ecyanomethanimine, using IRAM 30m observations towards the Galactic Center quiescent molecular cloud G+0.693. The Z-isomer has a column density of (2.0±0.6)×10 14 cm −2 and an abundance of 1.5×10 −9 . The relative abundance ratio between the isomers is [Z/E]∼6. This value cannot be explained by the two chemical formation routes previously proposed (gas-phase and grain surface), which predicts abundances ratios between 0.9 and 1.5. The observed [Z/E] ratio is in good agreement with thermodynamic equilibrium at the gas kinetic temperature (130−210 K). Since isomerization is not possible in the ISM, the two species may be formed at high temperature. New chemical models, including surface chemistry on dust grains and gas-phase reactions, should be explored to explain our findings. Whatever the formation mechanism, the high abundance of Z-HNCHCN shows that precursors of adenine are efficiently formed in the ISM.

show abstract

“…Indeed, Eshchenko et al (2002) and Glarborg et al (1998) have shown that the HCCO + NO HCNO + CO could be an important pathway to form or destroy HCNO. The recent detection of unexpected high abundances of HCCO toward cold dark clouds (Agúndez et al 2015) favours this idea. Glarborg et al (1998) also suggested that HCNO could be efficiently recycled to NO through the reaction with OH.…”

Section: Hnco and Isomersmentioning

confidence: 98%

Chemical modelling of complex organic molecules with peptide-like bonds in star-forming regions

Quénard

Jiménez-Serra

Viti

et al. 2017

Monthly Notices of the Royal Astronomical Society

102

124

View full text Add to dashboard Cite

Peptide bonds (N-C=O) play a key role in metabolic processes since they link amino acids into peptide chains or proteins. Recently, several molecules containing peptidelike bonds have been detected across multiple environments in the interstellar medium (ISM), growing the need to fully understand their chemistry and their role in forming larger pre-biotic molecules. We present a comprehensive study of the chemistry of three molecules containing peptide-like bonds: HNCO, NH 2 CHO, and CH 3 NCO. We also included other CHNO isomers (HCNO, HOCN), and C 2 H 3 NO isomers (CH 3 OCN, CH 3 CNO) to the study. We have used the uclchem gas-grain chemical code and included in our chemical network all possible formation/destruction pathways of these peptide-like molecules recently investigated either by theoretical calculations or in laboratory experiments. Our predictions are compared to observations obtained toward the proto-star IRAS16293-2422 and the L1544 pre-stellar core. Our results show that some key reactions involving the CHNO and C 2 H 3 NO isomers need to be modified to match the observations. Consistently with recent laboratory findings, hydrogenation is unlikely to produce NH 2 CHO on grain surfaces, while a combination of radicalradical surface reactions and gas-phase reactions is a better alternative. In addition, better results are obtained for NH 2 CHO when a slightly higher activation energy of 25 K is considered for the gas-phase reaction NH 2 + H 2 CO → NH 2 CHO + H. Finally, our modelling shows that the observed correlation between NH 2 CHO and HNCO in star-forming regions may come from the fact that HNCO and NH 2 CHO react to temperature in the same manner rather than from a direct chemical link between the two species.

show abstract

Probing non-polar interstellar molecules through their protonated form: Detection of protonated cyanogen (NCCNH⁺)

Cited by 90 publications

References 40 publications

Detection of the HC3NH+ and HCNH+ ions in the L1544 pre-stellar core

Detection of the HC3NH+ and HCNH+ ions in the L1544 pre-stellar core

Abundant Z-cyanomethanimine in the interstellar medium: paving the way to the synthesis of adenine

Chemical modelling of complex organic molecules with peptide-like bonds in star-forming regions

Contact Info

Product

Resources

About

Probing non-polar interstellar molecules through their protonated form: Detection of protonated cyanogen (NCCNH+)

Cited by 90 publications

References 40 publications

Detection of the HC3NH+ and HCNH+ ions in the L1544 pre-stellar core

Detection of the HC3NH+ and HCNH+ ions in the L1544 pre-stellar core

Abundant Z-cyanomethanimine in the interstellar medium: paving the way to the synthesis of adenine

Chemical modelling of complex organic molecules with peptide-like bonds in star-forming regions

Contact Info

Product

Resources

About

Probing non-polar interstellar molecules through their protonated form: Detection of protonated cyanogen (NCCNH⁺)