Chiara Lazzeri, Andrey Samsonov, Colin Forsyth, Graziella Branduardi-Raymont, Yulia V. Bogdanova
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We analyze the maximum responses of the SML, SMU, SYM-H, and PCN magnetospheric indices and their timescales, along with the occurrence of geomagnetic phenomena. We find that most STs were followed by either substorms (60.20%) or enhanced convection (37.76%). While SML has similar median minima (∼−460 nT) and timescales (∼56 min) for substorm and convection events, SMU has noticeable differences. STs were followed by geomagnetic storms (SYM-H ≤ −50 nT) in 46.94% of events within 12 hr, with more storms following ICME-related turnings. PCN has peaks (median 3.8 mV/m) around 30 min after the turning, and larger ones (median 4.9 mV/m) later. Stronger solar wind driving and magnetospheric responses are observed for ICME-related events. 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引用次数: 0
摘要
行星际磁场(IMF)的南北分量 Bz 在太阳风与地球磁层的相互作用中起着至关重要的作用。我们分析了 98 个 Bz 在 5 分钟内从 >3 nT 变为 <-3 nT 的时间间隔,这些快速南转(STs)被持续向北或向南的 IMF 所包围。我们将行星际日冕物质抛射和冠状相互作用区域附近的事件区分开来。我们发现,转折点附近的 IMF 幅值、太阳风动压和质子密度(以及 ICME 相关事件中的流速)都比它们的中值要高。我们分析了 SML、SMU、SYM-H 和 PCN 磁层指数的最大响应及其时标,以及地磁现象的发生。我们发现,大多数 ST 之后都会出现亚暴(60.20%)或对流增强(37.76%)。虽然 SML 的亚暴和对流事件的最小值中值(∼-460 nT)和时间尺度(∼56 分钟)相似,但 SMU 有明显差异。有 46.94%的 ST 事件在 12 小时内发生了地磁暴(SYM-H ≤ -50nT),更多的风暴发生在与 ICME 有关的转向之后。PCN 在转折后 30 分钟左右出现峰值(中值 3.8 mV/m),随后出现更大的峰值(中值 4.9 mV/m)。在与国际集成电磁脉冲事件相关的事件中观测到了更强的太阳风驱动和磁层响应。ST附近的地磁和太阳风参数之间的相关性表明,与其他时间相比,ST的太阳风驱动和地磁响应之间有更直接的联系。
A Statistical Study of the Properties of, and Geomagnetic Responses to, Large, Rapid Southward Turnings of the Interplanetary Magnetic Field
The interplanetary magnetic field (IMF) north-south component, Bz, plays a crucial role in the interaction between the solar wind and the Earth's magnetosphere. We analyze 98 intervals in which Bz changed from >3 nT to <−3 nT in 5 min and for which these rapid southward turnings (STs) were surrounded by consistently northward or southward IMF. We separate out events in proximity of interplanetary coronal mass ejections and corotating interaction regions. We find that IMF magnitude, solar wind dynamic pressure and proton density (but also flow speed in ICME-related events) near the turnings are enhanced above their medians. We analyze the maximum responses of the SML, SMU, SYM-H, and PCN magnetospheric indices and their timescales, along with the occurrence of geomagnetic phenomena. We find that most STs were followed by either substorms (60.20%) or enhanced convection (37.76%). While SML has similar median minima (∼−460 nT) and timescales (∼56 min) for substorm and convection events, SMU has noticeable differences. STs were followed by geomagnetic storms (SYM-H ≤ −50 nT) in 46.94% of events within 12 hr, with more storms following ICME-related turnings. PCN has peaks (median 3.8 mV/m) around 30 min after the turning, and larger ones (median 4.9 mV/m) later. Stronger solar wind driving and magnetospheric responses are observed for ICME-related events. The correlation between the geomagnetic and solar wind parameters around STs reveals a more direct link between solar wind driving and geomagnetic response for STs than at other times.
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