从hi - 21cm发射吸收光谱测量中性ISM中的湍流

IF 4.5 3区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Publications of the Astronomical Society of Australia Pub Date : 2023-08-03 DOI:10.1017/pasa.2023.43

Atanu Koley

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引用次数: 1

摘要

摘要:本文研究了中性星际介质(ISM)中非热速度色散($\sigma_{n}$)与长度尺度(L)之间的关系，使用了从各种已发表的Hi调查和以前的Hi研究中获得的大量Hi气体成分。我们注意到，在0.40 pc的长度尺度(L)以上，$\sigma_{nth}$与L之间存在幂律关系。然而，在0.40 pc以下，幂律中断，其中$\sigma_{nth}$与L不显着相关。从马尔可夫链蒙特卡罗(MCMC)方法中观察到，对于L $\gt$ 0.40 pc的数据集，强度(a)和幂律指数(p)的最可能值分别为1.14和0.55。p的结果表明，幂律比湍流的标准Kolmogorov定律更陡峭。这是由于云层在冷中性介质中占主导地位。当我们将云分为两类时，这一点就更加清楚了:一类是L为$\gt$ 0.40 pc，动力学温度($T_{k}$)为$\lt$ 250k，处于冷中性介质(CNM)中;另一类是L为$\gt$ 0.40 pc， $T_{k}$在250至5 000 k之间，处于热不稳定相(UNM)。在CNM阶段，A和p的最可能值分别为1.14和0.67，在UNM阶段，A和p的最可能值分别为1.01和0.52。由于UNM阶段的大多数云位于500k以下，因此更多的数据点对于构建更准确的A和p估计是有效的。然而，从CNM阶段的p值来看，似乎与Kolmogorov标度存在显着差异，这可以归因于激波主导的介质。

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Turbulence measurements in the neutral ISM from Hi-21 cm emission–absorption spectra

Abstract We study the correlation between the non-thermal velocity dispersion ( $\sigma_{nth}$ ) and the length scale (L) in the neutral interstellar medium (ISM) using a large number of Hi gas components taken from various published Hi surveys and previous Hi studies. We notice that above the length-scale (L) of 0.40 pc, there is a power-law relationship between $\sigma_{nth}$ and L. However, below 0.40 pc, there is a break in the power law, where $\sigma_{nth}$ is not significantly correlated with L. It has been observed from the Markov chain Monte Carlo (MCMC) method that for the dataset of L $\gt$ 0.40 pc, the most probable values of intensity (A) and power-law index (p) are 1.14 and 0.55, respectively. Result of p suggests that the power law is steeper than the standard Kolmogorov law of turbulence. This is due to the dominance of clouds in the cold neutral medium. This is even more clear when we separate the clouds into two categories: one for L is $\gt$ 0.40 pc and the kinetic temperature ( $T_{k}$ ) is $\lt$ 250 K, which are in the cold neutral medium (CNM) and for other one where L is $\gt$ 0.40 pc and $T_{k}$ is between 250 and 5 000 K, which are in the thermally unstable phase (UNM). Most probable values of A and p are 1.14 and 0.67, respectively, in the CNM phase and 1.01 and 0.52, respectively, in the UNM phase. A greater number of data points is effective for the UNM phase in constructing a more accurate estimate of A and p, since most of the clouds in the UNM phase lie below 500 K. However, from the value of p in the CNM phase, it appears that there is a significant difference from the Kolmogorov scaling, which can be attributed to a shock-dominated medium.

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来源期刊

Publications of the Astronomical Society of Australia 地学天文-天文与天体物理

CiteScore

5.90

自引率

9.50%

发文量

审稿时长

>12 weeks

期刊介绍： Publications of the Astronomical Society of Australia (PASA) publishes new and significant research in astronomy and astrophysics. PASA covers a wide range of topics within astronomy, including multi-wavelength observations, theoretical modelling, computational astronomy and visualisation. PASA also maintains its heritage of publishing results on southern hemisphere astronomy and on astronomy with Australian facilities. PASA publishes research papers, review papers and special series on topical issues, making use of expert international reviewers and an experienced Editorial Board. As an electronic-only journal, PASA publishes paper by paper, ensuring a rapid publication rate. There are no page charges. PASA''s Editorial Board approve a certain number of papers per year to be published Open Access without a publication fee.