Solar Surface Magneto-Convection

IF 23 1区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Living Reviews in Solar Physics Pub Date : 2012-07-19 DOI:10.12942/lrsp-2012-4

Robert F. Stein

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引用次数: 4

Abstract

We review the properties of solar magneto-convection in the top half of the convection zones scale heights (from 20 Mm below the visible surface to the surface, and then through the photosphere to the temperature minimum). Convection is a highly non-linear and nonlocal process, so it is best studied by numerical simulations. We focus on simulations that include sufficient detailed physics so that their results can be quantitatively compared with observations.

The solar surface is covered with magnetic features with spatial sizes ranging from unobservably small to hundreds of megameters. Three orders of magnitude more magnetic flux emerges in the quiet Sun than emerges in active regions. In this review we focus mainly on the properties of the quiet Sun magnetic field.

The Sun's magnetic field is produced by dynamo action throughout the convection zone, primarily by stretching and twisting in the turbulent downflows. Diverging convective upflows and magnetic buoyancy carry magnetic flux toward the surface and sweep the field into the surrounding downflow lanes where the field is dragged downward. The result is a hierarchy of undulating magnetic Ω- and U-loops of different sizes. New magnetic flux first appears at the surface in a mixed polarity random pattern and then collects into isolated unipolar regions due to underlying larger scale magnetic structures. Rising magnetic structures are not coherent, but develop a filamentary structure. Emerging magnetic flux alters the convection properties, producing larger, darker granules.

Strong field concentrations inhibit transverse plasma motions and, as a result, reduce convective heat transport toward the surface which cools. Being cooler, these magnetic field concentrations have a shorter scale height and become evacuated. The field becomes further compressed and can reach strengths in balance with the surrounding gas pressure. Because of their small internal density, photons escape from deeper in the atmosphere. Narrow evacuated field concentrations get heated from their hot sidewalls and become brighter than their surroundings. Wider magnetic concentrations are not heated so they become darker, forming pores and sunspots.

Abstract Image

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太阳表面磁对流

我们回顾了对流区的上半部分尺度高度(从可见表面以下20 Mm到表面，然后通过光球到温度最低)的太阳磁对流特性。对流是一个高度非线性和非局部的过程，因此最好通过数值模拟来研究。我们专注于模拟，包括足够详细的物理，以便他们的结果可以定量地与观测进行比较。太阳表面覆盖着空间大小从难以察觉的小到数百兆欧米的磁性特征。在安静的太阳中出现的磁通量比在活跃区域出现的磁通量多三个数量级。在这篇综述中，我们主要集中在安静的太阳磁场的性质。太阳的磁场是由整个对流区的发电机作用产生的，主要是由湍流下行流中的拉伸和扭曲产生的。发散的对流上升流和磁浮力将磁通量带到地表，并将磁场扫向周围的下行通道，在那里磁场被向下拖拽。结果是不同大小的波纹磁Ω和u形环的层次结构。新的磁通量首先以混合极性随机模式出现在表面，然后由于潜在的更大规模磁结构而聚集成孤立的单极区。上升磁结构不是连贯的，而是呈丝状结构。新产生的磁通量改变了对流特性，产生了更大、更暗的颗粒。强场浓度抑制等离子体的横向运动，从而减少向表面冷却的对流热传输。由于温度较低，这些磁场浓度具有较短的尺度高度并被疏散。油田被进一步压缩，可以达到与周围气体压力平衡的强度。由于其内部密度小，光子从大气层深处逃逸。狭窄的真空场集中从它们的热侧壁受热，变得比周围更亮。更大的磁场浓度没有被加热，所以它们变得更暗，形成孔隙和太阳黑子。

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

Living Reviews in Solar Physics Earth and Planetary Sciences-Space and Planetary Science

CiteScore

41.90

自引率

1.40%

发文量

审稿时长

20 weeks

期刊介绍： Living Reviews in Solar Physics is a peer-reviewed, full open access, and exclusively online journal, publishing freely available reviews of research in all areas of solar and heliospheric physics. Articles are solicited from leading authorities and are directed towards the scientific community at or above the graduate-student level. The articles in Living Reviews provide critical reviews of the current state of research in the fields they cover. They evaluate existing work, place it in a meaningful context, and suggest areas where more work and new results are needed. Articles also offer annotated insights into the key literature and describe other available resources. Living Reviews is unique in maintaining a suite of high-quality reviews, which are kept up-to-date by the authors. This is the meaning of the word "living" in the journal''s title.