探索全球 MHD 中的局部地磁扰动:物理学与数值学

IF 3.7 2区 地球科学 Space Weather Pub Date : 2024-04-08 DOI:10.1029/2023sw003799
Erik M. Vandegriff, Daniel T. Welling, Agnit Mukhopadhyay, Andrew P. Dimmock, Steven K. Morley, Ramon E. Lopez
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引用次数: 0

摘要

空间天气的突出影响之一是在磁层-电离层系统的驱动下在地球表面形成快速的地磁场变化。这些地磁扰动(GMDs)导致地磁感应电流穿过地面传导系统。特别是,局部地磁扰动(LGMDs)的振幅可能很高,对小于 100 公里的尺度也会产生影响,因此对电网造成危害,而且难以预测。在本研究中,我们利用现有指标和新指标,考察了空间天气建模框架(SWMF)在 2017 年 9 月 7 日事件中再现 LGMD 的能力,以量化模型与观测的成功率。我们表明,高分辨率 SWMF 能够再现电离层源驱动的 LGMD,但难以再现亚暴效应驱动的 LGMD。我们计算了磁波动的全局最大值,以显示 SWMF 在正确的时间捕捉到 LGMD 的情况,但没有捕捉到正确的位置。为了弥补这些缺陷,我们建议对模型进行开发,这将直接影响到 SWMF 重现 LGMD 的能力,其中最重要的是更新电离层电导计算,从经验计算改为物理计算。
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Exploring Localized Geomagnetic Disturbances in Global MHD: Physics and Numerics
One of the prominent effects of space weather is the formation of rapid geomagnetic field variations on Earth's surface driven by the magnetosphere-ionosphere system. These geomagnetic disturbances (GMDs) cause geomagnetically induced currents to run through ground conducting systems. In particular, localized GMDs (LGMDs) can be high amplitude and can have an effect on scale sizes less than 100 km, making them hazardous to power grids and difficult to predict. In this study, we examine the ability of the Space Weather Modeling Framework (SWMF) to reproduce LGMDs in the 7 September 2017 event using both existing and new metrics to quantify the success of the model against observation. We show that the high-resolution SWMF can reproduce LGMDs driven by ionospheric sources, but struggles to reproduce LGMDs driven by substorm effects. We calculate the global maxima of the magnetic fluctuations to show instances when the SWMF captures LGMDs at the correct times but not the correct locations. To remedy these shortcomings we suggest model developments that will directly impact the ability of the SWMF to reproduce LGMDs, most importantly updating the ionospheric conductance calculation from empirical to physics-based.
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