Molecular chemistry induced by a J-shock toward supernova remnant W51C

IF 5.4 2区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS Astronomy & Astrophysics Pub Date : 2025-01-20 DOI:10.1051/0004-6361/202452270

Tian-Yu Tu, Valentine Wakelam, Yang Chen, Ping Zhou, Qian-Qian Zhang

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Abstract

Context. Shock waves from supernova remnants (SNRs) strongly affect the physical and chemical properties of molecular clouds (MCs). Shocks propagating into magnetized MCs can be classified into jump or J-shocks and continuous or C-shocks. The molecular chemistry in the re-formed molecular gas behind J-shocks is still only poorly understood. It is expected to provide a comprehensive view of the chemical feedback of SNRs and the chemical effects of J-shocks.Aims. We conducted a W-band (71.4–89.7 GHz) observation toward a re-formed molecular clump behind a J-shock induced by SNR W51C with the Yebes 40 m radio telescope to study the molecular chemistry in the re-formed molecular gas.Methods. Assuming local thermodynamic equilibrium (LTE), we estimated the column densities of HCO^{+^{, HCN, C_{2_{H and o-c-C_{3_{H_{2_{, and derived their abundance ratio maps with CO. The gas density was constrained by a non-LTE analysis of the HCO^{+^{J = 1–0 line. The abundance ratios were compared with the values in typical quiescent MCs and shocked MCs, and they were also compared with the results of chemical simulations with the Paris-Durham shock code to verify and investigate the chemical effects of J-shocks.Results. We obtained the following abundance ratios: N(HCO^{+^{)/N(CO) ~ (1.0–4.0) × 10^{−4^{, N(HCN)/N(CO) ~ (1.8–5.3) × 10^{−4^{, N(C_{2_{H)/N(CO) ~ (1.6–5.0) × 10^{−3^{, and N(o-c-C_{3_{H_{2_{)/N(CO) ~ (1.2–7.9) × 10^{−4^{. The non-LTE analysis suggests that the gas density is n_{H_{2_{_{≳ 10^{4^{cm^{−3^{. We find that the N(C_{2_{H)/N(CO) and N(o-c-C_{3_{H_{2_{)/N(CO) are higher than typical values in quiescent MCs and shocked MCs by 1–2 orders of magnitude, which can be qualitatively attributed to the abundant C^{+^{and C in the earliest phase of molecular gas re-formation. The Paris-Durham shock code can reproduce, although not perfectly, the observed abundance ratios, especially the enhanced N(C_{2_{H)/N(CO) and N(c-C_{3_{H_{2_{)/N(CO), with J-shocks propagating into both nonirradiated and irradiated molecular gas with a preshock density of n_{H_{= 2 × 10^{3^{cm^{−3^.}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}}

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超新星遗迹W51C的j激波诱导的分子化学

上下文。超新星残余物的激波对分子云的物理和化学性质有强烈的影响。传播到磁化mc中的冲击可以分为跳变或j型冲击和连续或c型冲击。在j激波后重新形成的分子气体中的分子化学仍然知之甚少。期望对信噪比的化学反馈和j冲击的化学效应提供一个全面的看法。利用Yebes 40 m射电望远镜对SNR W51C诱发的j激波后的重构分子团块进行了w波段（71.4 ~ 89.7 GHz）观测，研究了重构分子气体中的分子化学性质。假设局部热力学平衡（LTE），我们估计了HCO+， HCN， C2H和o-c-C3H2的柱密度，并得到了它们与CO的丰度比图。气体密度受到HCO+ J = 1-0线的非LTE分析的约束。将丰度比与典型的静止MCs和受冲击MCs的丰度比进行了比较，并与Paris-Durham激波代码的化学模拟结果进行了比较，以验证和研究j激波的化学效应。我们得到以下丰富比率:N (HCO +) / N (CO) ~ -4.0(1.0)×10−4,N (HCN) / N (CO) ~ -5.3(1.8)×10−4,N (C2H) / N (CO) ~ -5.0(1.6)×10−3,和N (o-c-C3H2) / N (CO) ~(1.2 - -7.9)×10−4。非lte分析表明气体密度为nH2≥104 cm−3。研究发现，在静止和震荡过程中，N(C2H)/N（CO）和N(o-c-C3H2)/N（CO）比典型值高1-2个数量级，这可以定性地归因于分子气体重构早期丰富的C+和C。当冲击前密度为nH = 2 × 103 cm−3的j -激波同时传播到未辐照和辐照的分子气体中时，Paris-Durham激波编码虽然不能完美地再现所观察到的丰度比，尤其是增强的N(C2H)/N（CO）和N(c-C3H2)/N（CO）。

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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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