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磁性、发电机效应与太阳-恒星联系。

Magnetism, dynamo action and the solar-stellar connection.

作者信息

Brun Allan Sacha, Browning Matthew K

机构信息

Laboratoire AIM, DRF/IRFU/Département d'Astrophysique, CEA-Saclay, 91191 Gif-sur-Yvette France.

2Department of Physics and Astronomy, University of Exeter, Stocker Road, Exeter, EX4 4QL UK.

出版信息

Living Rev Sol Phys. 2017;14(1):4. doi: 10.1007/s41116-017-0007-8. Epub 2017 Sep 26.

DOI:10.1007/s41116-017-0007-8
PMID:31997984
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6956918/
Abstract

The Sun and other stars are magnetic: magnetism pervades their interiors and affects their evolution in a variety of ways. In the Sun, both the fields themselves and their influence on other phenomena can be uncovered in exquisite detail, but these observations sample only a moment in a single star's life. By turning to observations of other stars, and to theory and simulation, we may infer other aspects of the magnetism-e.g., its dependence on stellar age, mass, or rotation rate-that would be invisible from close study of the Sun alone. Here, we review observations and theory of magnetism in the Sun and other stars, with a partial focus on the "Solar-stellar connection": i.e., ways in which studies of other stars have influenced our understanding of the Sun and vice versa. We briefly review techniques by which magnetic fields can be measured (or their presence otherwise inferred) in stars, and then highlight some key observational findings uncovered by such measurements, focusing (in many cases) on those that offer particularly direct constraints on theories of how the fields are built and maintained. We turn then to a discussion of how the fields arise in different objects: first, we summarize some essential elements of convection and dynamo theory, including a very brief discussion of mean-field theory and related concepts. Next we turn to simulations of convection and magnetism in stellar interiors, highlighting both some peculiarities of field generation in different types of stars and some unifying physical processes that likely influence dynamo action in general. We conclude with a brief summary of what we have learned, and a sampling of issues that remain uncertain or unsolved.

摘要

太阳和其他恒星都具有磁性

磁性贯穿它们的内部,并以多种方式影响其演化。在太阳中,磁场本身及其对其他现象的影响都能被极为详细地揭示出来,但这些观测仅仅采样了一颗恒星生命中的某一时刻。通过转向对其他恒星的观测以及理论和模拟,我们可以推断出磁性的其他方面,例如其对恒星年龄、质量或自转速率的依赖性,而这些仅通过对太阳的深入研究是无法发现的。在这里,我们回顾太阳和其他恒星磁性的观测和理论,部分聚焦于“太阳 - 恒星联系”,即对其他恒星的研究影响我们对太阳理解的方式,反之亦然。我们简要回顾在恒星中测量磁场(或推断其存在)的技术,然后突出此类测量所揭示的一些关键观测结果,(在许多情况下)重点关注那些对磁场如何形成和维持的理论提供特别直接约束的结果。接着我们讨论磁场在不同天体中是如何产生的:首先,我们总结对流和发电机理论的一些基本要素,包括对平均场理论及相关概念的简要讨论。接下来我们转向恒星内部对流和磁性的模拟,突出不同类型恒星中磁场产生的一些独特之处以及一些可能普遍影响发电机作用的统一物理过程。我们最后简要总结我们所学到的内容,以及一些仍不确定或未解决的问题。

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