Long-Range Correlations in 2D Structures of the Magnetic Field Dissipation in the Photosphere of Solar Active Regions

IF 0.7 4区地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS

Geomagnetism and Aeronomy Pub Date : 2025-01-16 DOI:10.1134/S0016793224700014

V. I. Abramenko, R. A. Suleymanova, A. S. Kutsenko

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Abstract

Vector-magnetograms acquired by the Helioseismic and Magnetic Imager (HMI) onboard the Solar Dynamics Observatory (SDO) were utilized to explore the spatial correlation functions of the dissipative structures, such as the vertical magnetic field dissipation, E_diss, the squared density of the vertical electric current, \(J_{z}^{2}\), the current helicity density, H_c. Six mature active regions (ARs) were explored, three of them belong to the magneto-morphological class (MMC) A1—regular ARs that follow the empirical rules of the Babcock-Leighton dynamo theory, and the rest three ARs belong to the MMC B3 class, irregular multipolar ARs. We found that, on the contrary to the vertical magnetic field structures (see (Abramenko, Suleymanova 2024)), all considered here dissipative structures reveal a range of the power law in the correlation function. Parameters of the power law vary significantly for different types of the considered structures and for different ARs of different classes. The most pronounced difference in the power law parameters between the AR’s classes was found for both \(J_{z}^{2}\) and H_c: the B3-class ARs demonstrate a capability for longer correlations and shallower power law slope than the A1-class ARs do. As soon as the power law correlation function is thought to indicate the self-organized criticality (SOC) state, we might conclude that in the photosphere, the SOC is rather observable in the magnetic dissipative structures, than in the magnetic field itself; a signature of SOC seems to be stronger manifested in the complex irregular B3-class ARs with high flaring activity. The proposed approach can facilitate to find a connection between the photosphere and upper layers in setting up the critical state, which is necessary for eruptions of all scales.

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太阳活动区光球磁场耗散二维结构的长程相关

利用太阳动力学观测台（SDO）上的日震磁成像仪（HMI）获取的矢量磁图，探讨了垂直磁场耗散、Ediss、垂直电流平方密度\(J_{z}^{2}\)、电流螺旋密度Hc等耗散结构的空间相关函数。共发现6个成熟活动区，其中3个为遵循Babcock-Leighton发电机理论经验规律的磁形态类a1规则活动区，其余3个为不规则多极MMC B3类活动区。我们发现，与垂直磁场结构相反（见（Abramenko, Suleymanova 2024）），这里考虑的所有耗散结构都在相关函数中显示出一系列幂律。对于所考虑的不同类型的结构和不同类别的不同ar，幂律的参数变化很大。对于\(J_{z}^{2}\)和Hc，幂律参数在AR类之间的差异最为明显：b3类AR比a1类AR具有更长的相关性和更浅的幂律斜率。只要认为幂律相关函数表示自组织临界状态，我们就可以得出结论，在光球中，自组织临界状态在磁耗散结构中比在磁场本身中更容易观察到；在具有高燃烧活性的复杂不规则的b3类ARs中，有机碳的特征似乎更明显。所提出的方法有助于找到光球层与上层之间建立临界状态的联系，这对于所有规模的喷发都是必要的。

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来源期刊

Geomagnetism and Aeronomy Earth and Planetary Sciences-Space and Planetary Science

CiteScore

1.30

自引率

33.30%

发文量

审稿时长

4-8 weeks

期刊介绍： Geomagnetism and Aeronomy is a bimonthly periodical that covers the fields of interplanetary space; geoeffective solar events; the magnetosphere; the ionosphere; the upper and middle atmosphere; the action of solar variability and activity on atmospheric parameters and climate; the main magnetic field and its secular variations, excursion, and inversion; and other related topics.