Katharina N. Maetschke, Elena A. Kronberg, Noora Partamies, Elena E. Grigorenko
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引用次数: 0
摘要
不同的理论描述了极光螺旋的产生过程,它们的形态和周围条件各不相同。本文提出了2013年9月18日在挪威特罗姆瑟观测到的一个向东移动的极光螺旋的可能机制。来自THEMIS-A和Cluster航天器的测量结果进行了分析,它们位于磁层中螺旋发生器区域向暗约10 R E处。在此之前,星系团卫星在距离地球13.6 ~ 14.2 R E的径向距离上测量了同步磁场双极化、爆发流和电子注入。同时,在磁场中发现了一个局部的类似开尔文-亥姆霍兹的涡旋街,这可能是由突发的大块流引起的。旋涡街大致在X-Y (GSE)平面上,由于流爆发中较高的向南速度分量,可能向螺旋源区域传播。观测结果表明,螺旋可能是由磁尾中相关的涡流产生的,然后沿着磁力线映射到电离层。为了更好地了解电离层在极光螺旋产生中的作用,未来需要更多的中尺度观测。
A possible mechanism for the formation of an eastward moving auroral spiral
The generation process of auroral spirals is described by different theories varying for their morphology and surrounding conditions. Here, a possible mechanism is proposed for an eastward moving auroral spiral, which was observed in Tromsø, Norway, during the expansion phase of a substorm on 18 September 2013. Measurements from the THEMIS-A and Cluster spacecraft were analyzed, which were located up to ∼10 R E duskward from the spiral generator region in the magnetosphere. Precursory to the spiral observation, concurrent magnetic field dipolarizations, flow bursts and electron injections were measured by the Cluster satellites between 13.6 and 14.2 R E radial distance from Earth. A local Kelvin-Helmholtz-like vortex street in the magnetic field was detected at the same time, which was likely caused by bursty bulk flows. The vortex street was oriented approximately in the X-Y (GSE) plane and presumably propagated towards the source region of the spiral due to a high dawnward velocity component in the flow bursts. The observations suggest that the spiral can have been generated by an associated vortex in the magnetotail and then mapped along the magnetic field lines to the ionosphere. To better understand the role of the ionosphere in auroral spiral generation, in future more mesoscale observations are required.