太阳深处小尺度磁波动激发的理论和观测迹象

IF 0.5 4区 物理与天体物理 Q4 ASTRONOMY & ASTROPHYSICS
V. N. Krivodubskij, N. M. Kondrashova
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引用次数: 0

摘要

当今的一个实际问题是寻找太阳深层小尺度磁场存在的观测证据。在这方面,作者分析了 Sokoloff 和 Khlystova 提出的理论标准,以区分隐藏在太阳对流区(SCZ)深处的两种质地不同的小尺度动力机制对太阳表面磁力的贡献[Astron. Nachr. 2010. 331. P. 82-87]。第一种机制确保了由于湍流运动与平均磁场的相互作用而产生小尺度磁场(宏观 MHD 的小尺度动力-1),而第二种机制则导致了由于高导等离子体的湍流脉动而产生的磁波动自激(经典 MHD 的扩散性小尺度动力-2)。所提标准的实质是,在某些条件下,深层小尺度磁场会导致太阳表面观测到的磁性违反黑尔定律和乔伊定律。通过对这些扰动的统计分析,我们可以确定两种小尺度磁场源的观测表现在演变过程中的差异,因为两种深层动力机制对表面磁性的贡献随太阳周期阶段的不同而变化。其中一个重要特征是太阳黑子反黑子群的比例(相对于太阳黑子总数)在周期中的表现。在小尺度动力-1 的情况下,反黑子群的百分比与周期阶段无关,而与弥散性小尺度动力-2 相关的反黑子群百分比应在太阳极小值时达到最大值。因此,磁异常的变化使我们有可能将两种小尺度动力机制对地表磁性的微弱贡献区分开来。因此,从观测结果中找出太阳深处小尺度动力机制的标记就变得非常重要。有鉴于此,我们对长期观测到的一系列违反黑尔定律和乔伊定律现象的统计研究文献数据进行了分析。特别是,Sokoloff、Khlystova 和 Abramenko [Mon. Notic. Roy. Astron. Soc. 2015. 451. P. 1522-1527]在处理 1917-2004 年期间不同星表数据的基础上证明,在太阳周期的最小值期间,反黑尔点群的百分比会增加。这证明了在SCZ内部有一个扩散性的小尺度湍流动力-2在运行,其效率在接近周期的最小值时变得很明显,此时全球环形磁场减弱。作者对第 24 和 25 个太阳周期极值附近观测到的六个磁活跃区进行了分析,结果发现了对黑尔定律和乔伊定律的特征性违反,这可能表明扩散性小尺度动力-2 对这些区域的演变产生了影响,因为正是这个源对周期极值附近的表面磁性做出了最明显的贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Theoretical and Observed Signs of Excitation of Small-Scale Magnetic Fluctuations in the Depth of the Sun

Theoretical and Observed Signs of Excitation of Small-Scale Magnetic Fluctuations in the Depth of the Sun

An actual problem today is the search for observed evidence of the existence of deep small-scale magnetic fields of the Sun. In this regard, the authors analyzed the theoretical criterion for separating the contributions to the solar surface magnetism of two qualitatively different mechanisms of a small-scale dynamo, the action of which is hidden in the depths of the solar convection zone (SCZ), proposed by Sokoloff and Khlystova [Astron. Nachr. 2010. 331. P. 82–87]. The first mechanism ensures the generation of small-scale magnetic fields due to the interaction of turbulent motions with the mean magnetic field (small-scale dynamo-1 of macroscopic MHD), while the second mechanism causes self-excitation of magnetic fluctuations due to turbulent pulsations of highly conductive plasma ( diffusive small-scale dynamo-2 of classical MHD). The essence of the proposed criterion is that deep small-scale magnetic fields can lead under certain conditions to violations of Hale’s and Joy’s laws of observed magnetism on the surface of the Sun. Statistical analysis of these disturbances allows one to identify the differences in the evolution of the observed manifestations of two sources of small-scale fields since the contribution of two deep dynamo mechanisms to surface magnetism varies with the phase of the solar cycle in different ways. Such an important feature is the behavior of the percentage of anti-Hail groups of sunspots (in relation to the total number of sunspots) during the cycles. In the case of small-scale dynamo-1, the percentage of anti-Hale groups is independent of cycle phase, whereas the percentage of anti-Hale groups associated with diffusive small-scale dynamo-2 should reach its maximum value at solar minima. Therefore, the variations of magnetic anomalies make it possible to separate the meager contributions of two small-scale dynamo mechanisms to surface magnetism. In this connection, the task of identifying the markers of a small-scale dynamo in the solar depths from observations becomes relevant. With this in mind, we conducted an analysis of literature data of statistical studies of long series of observed violations of Hale’s and Joy’s laws, which can be caused by the presence of deep small-scale magnetic fluctuations of various origins. In particular, it was demonstrated in the work of Sokoloff, Khlystova, and Abramenko [Mon. Notic. Roy. Astron. Soc. 2015. 451. P. 1522–1527] on the basis of processing the data of different catalogs for the period 1917–2004 that the percentage of anti-Hale groups of spots increases during the minima of solar cycles. This testifies to the operation of a diffusive small-scale turbulent dynamo-2 within the SCZ, the efficiency of which becomes noticeable near the minima of the cycles, when the global toroidal magnetic field weakens. As a result of the authors' analysis of six magnetic active regions observed near the minima of the 24th and 25th solar cycles, characteristic violations of Hale’s and Joy’s laws were revealed, which may indicate the influence of a diffusive small-scale dynamo-2 on the evolution of these regions since it is this source that gives the most noticeable contribution in surface magnetism near cycles minima.

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来源期刊
Kinematics and Physics of Celestial Bodies
Kinematics and Physics of Celestial Bodies ASTRONOMY & ASTROPHYSICS-
CiteScore
0.90
自引率
40.00%
发文量
24
审稿时长
>12 weeks
期刊介绍: Kinematics and Physics of Celestial Bodies is an international peer reviewed journal that publishes original regular and review papers on positional and theoretical astronomy, Earth’s rotation and geodynamics, dynamics and physics of bodies of the Solar System, solar physics, physics of stars and interstellar medium, structure and dynamics of the Galaxy, extragalactic astronomy, atmospheric optics and astronomical climate, instruments and devices, and mathematical processing of astronomical information. The journal welcomes manuscripts from all countries in the English or Russian language.
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