Study of Reconnection Dynamics and Plasma Relaxation in MHD Simulation of a Solar Flare

IF 2.7 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
Satyam Agarwal, Ramit Bhattacharyya, Shangbin Yang
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Abstract

Self-organization in continuous systems is associated with dissipative processes. In particular, for magnetized plasmas, it is known as magnetic relaxation, where the magnetic energy is converted into heat and kinetic energy of flow through the process of magnetic reconnection. An example of such a system is the solar corona, where reconnection manifests as solar transients like flares and jets. Consequently, toward investigation of plasma relaxation in solar transients, we utilize a novel approach of data-constrained MHD simulation for an observed solar flare. The selected active region NOAA 12253 hosts a GOES M1.3 class flare. The investigation of extrapolated coronal magnetic field in conjunction with the spatiotemporal evolution of the flare reveals a hyperbolic flux tube (HFT), overlying the observed brightenings. MHD simulation is carried out with the EULAG-MHD numerical model to explore the corresponding reconnection dynamics. The overall simulation shows signatures of relaxation. For a detailed analysis, we consider three distinct subvolumes. We analyze the magnetic field line dynamics along with time evolution of physically relevant quantities like magnetic energy, current density, twist, and gradients in magnetic field. In the terminal state, none of the subvolumes is seen to reach a force-free state, thus remaining in nonequilibrium, suggesting the possibility of further relaxation. We conclude that the extent of relaxation depends on the efficacy and duration of reconnection, and hence on the energetics and time span of the flare.

Abstract Image

Abstract Image

太阳耀斑 MHD 模拟中的再连接动力学和等离子体弛豫研究
连续系统中的自组织与耗散过程有关。特别是对于磁化等离子体,它被称为磁弛豫,磁能通过磁重联过程转化为热能和流动动能。日冕就是这种系统的一个例子,在日冕中,重联表现为耀斑和喷流等太阳瞬变现象。因此,为了研究太阳瞬变中的等离子体弛豫,我们采用了一种新方法,即对观测到的太阳耀斑进行数据约束 MHD 模拟。所选的活动区 NOAA 12253 发生了一次 GOES M1.3 级耀斑。结合耀斑的时空演变对外推法日冕磁场的研究揭示了一个覆盖在观测到的增亮之上的双曲线通量管(HFT)。利用 EULAG-MHD 数值模型进行了 MHD 模拟,以探索相应的再连接动力学。整个模拟显示出弛豫的特征。为了进行详细分析,我们考虑了三个不同的子卷。我们分析了磁场线动态以及磁能、电流密度、扭转和磁场梯度等物理相关量的时间演化。在终端状态下,没有一个子卷达到无力状态,因此仍处于非平衡状态,这表明有可能发生进一步的弛豫。我们的结论是,弛豫的程度取决于再连接的效率和持续时间,因此也取决于耀斑的能量和时间跨度。
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来源期刊
Solar Physics
Solar Physics 地学天文-天文与天体物理
CiteScore
5.10
自引率
17.90%
发文量
146
审稿时长
1 months
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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