Olga K. Kutsenko, Valentina I. Abramenko, Alexander S. Kutsenko
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引用次数: 0
Abstract
Using the magnetic power spectrum approach, we explore the magnetic energy changes at different spatial scales in four moderate-size decaying active regions (ARs). We find the dominant energy variations to take place at large spatial scales while the energy at low scales changes insignificantly. The analysis of the energy transfer function allows us to conclude that the direct turbulent cascade might occur occasionally and does not significantly contribute to the flux budget. Instead, we confirm the turbulent erosion, along with turbulent diffusion, to be the dominant mechanisms of the AR decay. We also reveal a gradual monotonous convergence of two coherent sunspots of opposite magnetic polarities as the decay proceeds. The sunspots exhibit magnetic connection seen as plasma loops in UV images. We suppose that the convergence is a result of an AR-size \(\Omega \)-loop submergence beneath the photosphere.
利用磁功率谱方法,我们探索了四个中等大小衰变活动区(ARs)中不同空间尺度的磁能变化。我们发现主要的能量变化发生在大空间尺度上,而低尺度上的能量变化并不明显。通过对能量传递函数的分析,我们得出结论:直接的湍流级联可能偶尔发生,但对通量预算的贡献不大。相反,我们证实湍流侵蚀和湍流扩散是 AR 衰减的主要机制。我们还发现,随着衰变的进行,两个磁极相反的相干太阳黑子逐渐单调地汇聚在一起。在紫外图像中,这些太阳黑子呈现出等离子环状的磁连接。我们推测,这种汇聚是光球下一个 AR 大小(\Omega \)-环潜入的结果。
期刊介绍:
Solar Physics was founded in 1967 and is the principal journal for the publication of the results of fundamental research on the Sun. The journal treats all aspects of solar physics, ranging from the internal structure of the Sun and its evolution to the outer corona and solar wind in interplanetary space. Papers on solar-terrestrial physics and on stellar research are also published when their results have a direct bearing on our understanding of the Sun.
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