Ro-vibrational analysis of SiO in UV-irradiated environments

Q2 Physics and Astronomy

Molecular Astrophysics Pub Date : 2018-11-01 DOI:10.1016/j.molap.2018.09.001

Ziwei E. Zhang , R.S. Cumbee , P.C. Stancil , G.J. Ferland

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引用次数: 2

Abstract

SiO emission lines are important probes of chemical processes in diverse astrophysical environments, commonly observed in shocks associated with the outflows of young stellar objects, both low- and high-mass, and in the envelopes of evolved stars. Modelling SiO emission for conditions of non-local thermodynamic equilibrium (NLTE) requires collisional rate coefficients due to H₂, H, and He impact, with the first of these of limited availability. Unknown collisional rate coefficients are often estimated from known systems. For the case of SiO-H₂, rate coefficients have previously been adapted from a different collider, He, based on a reduced-mass scaling approach. Here, we construct comprehensive SiO collisional rate coefficients data with multiple colliders (H₂, He and H) and rovibrational transitions up to $v = 5$ and $J = 39$ . A reduced-potential scaling approach is used to estimate unknown collisional data. Using RADEX and Cloudy, we investigate the rotational and rovibrational SiO emission in various astrophysical environments, including photodissociation regions (PDR) and the envelope of VY Canis Majoris.

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紫外辐射环境下SiO的反振动分析

SiO发射线是不同天体物理环境中化学过程的重要探测器，通常在与年轻恒星物体流出相关的冲击中观察到，无论是低质量还是高质量，还是在演化恒星的包层中。非局部热力学平衡(NLTE)条件下的SiO发射建模需要由于H2, H和He撞击而产生的碰撞速率系数，其中第一个可用性有限。未知的碰撞率系数通常是从已知系统中估计出来的。对于SiO-H2，速率系数先前已经根据不同的对撞机He进行了调整，基于减少质量尺度的方法。在这里，我们用多个对撞机(H2, He和H)和高达v=5和J=39的旋转振动跃迁构建了综合的SiO碰撞速率系数数据。采用降势标度方法对未知碰撞数据进行估计。利用radx和Cloudy，我们研究了不同天体物理环境下的旋转和旋转振动SiO发射，包括光解离区(PDR)和大犬星VY的包络。

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

Molecular Astrophysics ASTRONOMY & ASTROPHYSICS-

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期刊介绍： Molecular Astrophysics is a peer-reviewed journal containing full research articles, selected review articles, and thematic issues. Molecular Astrophysics is a new journal where researchers working in planetary and exoplanetary science, astrochemistry, astrobiology, spectroscopy, physical chemistry and chemical physics can meet and exchange their ideas. Understanding the origin and evolution of interstellar and circumstellar molecules is key to understanding the Universe around us and our place in it and has become a fundamental goal of modern astrophysics. Molecular Astrophysics aims to provide a platform for scientists studying the chemical processes that form and dissociate molecules, and control chemical abundances in the universe, particularly in Solar System objects including planets, moons, and comets, in the atmospheres of exoplanets, as well as in regions of star and planet formation in the interstellar medium of galaxies. Observational studies of the molecular universe are driven by a range of new space missions and large-scale scale observatories opening up. With the Spitzer Space Telescope, the Herschel Space Observatory, the Atacama Large Millimeter/submillimeter Array (ALMA), NASA''s Kepler mission, the Rosetta mission, and more major future facilities such as NASA''s James Webb Space Telescope and various missions to Mars, the journal taps into the expected new insights and the need to bring the various communities together on one platform. The journal aims to cover observational, laboratory as well as computational results in the galactic, extragalactic and intergalactic areas of our universe.