What is the Role of Gravity, Turbulence and Magnetic Fields in High-mass Star Formation Clouds?

IF 1.8 4区物理与天体物理 Q3 ASTRONOMY & ASTROPHYSICS

Research in Astronomy and Astrophysics Pub Date : 2024-05-19 DOI:10.1088/1674-4527/ad3ec8

An-Xu Luo, Hong-Li Liu, Guang-Xing Li, Sirong Pan and Dong-Ting Yang

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Abstract

To explore the potential role of gravity, turbulence and magnetic fields in high-mass star formation in molecular clouds, this study revisits the velocity dispersion–size (σ–L) and density–size (ρ–L) scalings and the associated turbulent energy spectrum using an extensive data sample. The sample includes various hierarchical density structures in high-mass star formation clouds, across scales of 0.01–100 pc. We observe σ ∝ L0.26 and ρ ∝ L−1.54 scalings, converging toward a virial equilibrium state. A nearly flat virial parameter–mass (αvir−M) distribution is seen across all density scales, with αvir values centered around unity, suggesting a global equilibrium maintained by the interplay between gravity and turbulence across multiple scales. Our turbulent energy spectrum (E(k)) analysis, based on the σ–L and ρ–L scalings, yields a characteristic E(k) ∝ k−1.52. These findings indicate the potential significance of gravity, turbulence, and possibly magnetic fields in regulating dynamics of molecular clouds and high-mass star formation therein.

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重力、湍流和磁场在大质量恒星形成云中的作用是什么？

为了探索重力、湍流和磁场在分子云中高质恒星形成过程中的潜在作用，本研究利用大量数据样本重新研究了速度色散大小（σ-L）和密度大小（ρ-L）标度以及相关的湍流能谱。样本包括高质恒星形成云中的各种分层密度结构，尺度为 0.01-100 pc。我们观测到σ∝L0.26和ρ∝L-1.54的标度，趋近于病毒平衡态。在所有密度尺度上都可以看到一个近乎平坦的病毒参数-质量（αvir-M）分布，αvir 值集中在统一点附近，这表明在多个尺度上引力和湍流的相互作用维持着一个全球平衡。我们基于 σ-L 和 ρ-L 标度的湍流能谱（E(k)）分析得出了特征 E(k) ∝k-1.52。这些发现表明重力、湍流以及可能的磁场在调节分子云的动力学和其中的高质恒星形成方面具有潜在意义。

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

Research in Astronomy and Astrophysics 地学天文-天文与天体物理

CiteScore

3.20

自引率

16.70%

发文量

2599

审稿时长

6.0 months

期刊介绍： Research in Astronomy and Astrophysics (RAA) is an international journal publishing original research papers and reviews across all branches of astronomy and astrophysics, with a particular interest in the following topics: -large-scale structure of universe formation and evolution of galaxies- high-energy and cataclysmic processes in astrophysics- formation and evolution of stars- astrogeodynamics- solar magnetic activity and heliogeospace environments- dynamics of celestial bodies in the solar system and artificial bodies- space observation and exploration- new astronomical techniques and methods