A Comprehensive Simulation of Solar Wind Formation from the Solar Interior: Significant Cross-field Energy Transport by Interchange Reconnection near the Sun

The Astrophysical Journal Letters Pub Date : 2023-06-29 DOI:10.3847/2041-8213/acdde0

H. Iijima, Takuma Matsumoto, H. Hotta, S. Imada

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引用次数: 1

Abstract

The physical connection between thermal convection in the solar interior and the solar wind remains unclear due to their significant scale separation. Using an extended version of the three-dimensional radiative magnetohydrodynamic code RAMENS, we perform the first comprehensive simulation of the solar wind formation, starting from the wave excitation and the small-scale dynamo below the photosphere. The simulation satisfies various observational constraints as a slow solar wind emanating from the coronal hole boundary. The magnetic energy is persistently released in the simulated corona, showing a hot upward flow at the interface between open and closed fields. To evaluate the energetic contributions from Alfvén wave and interchange reconnection, we develop a new method to quantify the cross-field energy transport in the simulated atmosphere. The measured energy transport from closed coronal loops to open field accounts for approximately half of the total. These findings suggest a significant role of the supergranular-scale interchange reconnection in solar wind formation.

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太阳内部太阳风形成的综合模拟:太阳附近交换重联的重要跨场能量传输

太阳内部的热对流和太阳风之间的物理联系由于它们显著的尺度分离而仍然不清楚。利用三维辐射磁流体力学代码RAMENS的扩展版本，从波激发和光球层下的小型发电机开始，首次对太阳风的形成进行了全面的模拟。模拟结果满足各种观测条件，即从日冕洞边界处发出的缓慢太阳风。磁场能量在模拟日冕中持续释放，在开、闭磁场界面处呈现出向上的热流。为了评估alfvsamn波和交换重连的能量贡献，我们提出了一种新的方法来量化模拟大气中的跨场能量输运。测量到的从闭合日冕环到开放磁场的能量输运约占总量的一半。这些发现提示了超颗粒尺度的交换重联在太阳风形成中的重要作用。

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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The Astrophysical Journal Letters

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