Detection of thioacetaldehyde (CH3CHS) in TMC-1: Sulfur-oxygen differentiation along the hydrogenation sequence⋆

IF 5.8 2区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS Astronomy & Astrophysics Pub Date : 2025-01-28 DOI:10.1051/0004-6361/202453459

M. Agúndez, G. Molpeceres, C. Cabezas, N. Marcelino, B. Tercero, R. Fuentetaja, P. de Vicente, J. Cernicharo

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Abstract

In recent years, the chemistry of sulfur in the interstellar medium has experienced renewed interest due to the detection of a large variety of molecules containing sulfur. We report the first identification in space of a new S-bearing molecule, thioacetaldehyde (CH_{3_{CHS), which is the sulfur counterpart of acetaldehyde (CH_{3_{CHO). The astronomical observations are part of QUIJOTE, a Yebes 40 m Q-band line survey of the cold dense cloud TMC-1. We detected seven individual lines corresponding to A and E components of the four most favorable rotational transitions of CH_{3_{CHS covered in the Q band (31.0–50.3 GHz). Assuming a rotational temperature of 9 K, we derive a column density of 9.8 × 10^{10^{cm^{−2^{for CH_{3_{CHS, which implies that it is 36 times less abundant than its oxygen counterpart CH_{3_{CHO. By comparing the column densities of the O- and S-bearing molecules detected in TMC-1, we find that as molecules increase their degree of hydrogenation, sulfur-bearing molecules become less abundant than their oxygen analog. That is, hydrogenation seems to be less favored for S-bearing molecules than for O-bearing ones in cold sources such as TMC-1. We explored potential formation pathways to CH_{3_{CHS and implemented them into a chemical model, which underestimates the observed abundance of thioacetaldehyde by several orders of magnitude, however. Quantum chemical calculations carried out for one of the potential formation pathways, the S + C_{2_{H_{5_{reaction, indicate that formation of CH_{3_{CHS is only a minor channel in this reaction.}}}}}}}}}}}}}}}}}}}}}}

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TMC-1中硫乙醛（CH3CHS）的检测：沿氢化序列的硫氧分化

近年来，由于检测到大量含硫分子，星际介质中硫的化学性质重新引起了人们的兴趣。我们报告了在空间中首次鉴定出一种新的含s分子，硫代乙醛（CH3CHS），它是乙醛（CH3CHO）的硫对应物。天文观测是QUIJOTE的一部分，QUIJOTE是Yebes对冷致密云TMC-1进行的40米q波段线调查。我们在Q波段（31.0-50.3 GHz）检测到CH3CHS的4个最有利旋转跃迁的A和E分量对应的7条单独的谱线。假设旋转温度为9 K，我们得出CH3CHS的柱密度为9.8 × 1010 cm−2，这意味着它的丰度比氧对应的CH3CHO少36倍。通过比较TMC-1中检测到的含O和含s分子的柱密度，我们发现随着分子加氢程度的增加，含硫分子的丰度比含氧分子少。也就是说，在冷源（如TMC-1）中，含s分子的氢化作用似乎比含o分子的氢化作用更不利。我们探索了CH3CHS的潜在形成途径，并将其应用到化学模型中，然而，该模型低估了观察到的硫乙醛丰度的几个数量级。对S + C2H5反应这一潜在生成途径进行的量子化学计算表明，CH3CHS的生成只是该反应的一个次要通道。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Astronomy & Astrophysics 地学天文-天文与天体物理

CiteScore
10.20

自引率
27.70%

发文量
2105

审稿时长
1-2 weeks

期刊介绍： Astronomy & Astrophysics is an international Journal that publishes papers on all aspects of astronomy and astrophysics (theoretical, observational, and instrumental) independently of the techniques used to obtain the results.

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