2a结果:星系到云的尺度

IF 2.6 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
Clare Dobbs
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引用次数: 0

摘要

从孤立星系到云的尺度的模拟在告诉我们分子云的形成和演化方面发挥了重要作用。模拟能够研究重力、反馈、湍流、加热和冷却以及磁场对星际介质和恒星形成的物理作用。与单个云的模拟相比,星系和亚星系尺度的模拟可以包括更大的星系尺度过程,如螺旋臂、棒状和更大的超新星气泡,这些过程可能会影响恒星的形成。模拟所显示的云的性质和寿命与观测结果基本一致。引力和旋臂需要产生更大质量的gmc,而恒星反馈,可能是光电离,导致云的寿命相对较短。在更大的尺度上,超新星在驱动结构和动力学方面可能更占主导地位,但光电离可能仍然有作用。在动力学方面,反馈可能是速度色散的主要驱动因素,但像重力和螺旋臂这样的大规模过程也可能是重要的。在星系或云尺度上,磁场通常会减少恒星的形成,在星系尺度模拟中,云在不同尺度上是亚临界还是超临界的模拟正在进行中。在亚星系尺度上的模拟,或放大模拟,可以更好地解决反馈过程、云中丝状结构和星团的研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
2a Results: galaxy to cloud scales
Simulations from the scales of isolated galaxies to clouds have been instrumental in informing us about molecular cloud formation and evolution. Simulations are able to investigate the roles of gravity, feedback, turbulence, heating and cooling, and magnetic fields on the physics of the interstellar medium, and star formation. Compared to simulations of individual clouds, galactic and sub-galactic scale simulations can include larger galactic scale processes such as spiral arms, bars, and larger supernovae bubbles, which may influence star formation. Simulations show cloud properties and lifetimes in broad agreement with observations. Gravity and spiral arms are required to produce more massive GMCs, whilst stellar feedback, likely photoionisation, leads to relatively short cloud lifetimes. On larger scales, supernovae may be more dominant in driving the structure and dynamics, but photoionisation may still have a role. In terms of the dynamics, feedback is probably the main driver of velocity dispersions, but large scale processes such as gravity and spiral arms may also be significant. Magnetic fields are generally found to decrease star formation on galaxy or cloud scales, and simulations are ongoing to study whether clouds are sub or supercritical on different scales in galaxy scale simulations. Simulations on subgalactic scales, or zoom in simulations, allow better resolution of feedback processes, filamentary structure within clouds, and the study of stellar clusters.
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来源期刊
Frontiers in Astronomy and Space Sciences
Frontiers in Astronomy and Space Sciences ASTRONOMY & ASTROPHYSICS-
CiteScore
3.40
自引率
13.30%
发文量
363
审稿时长
14 weeks
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