创建和研究按比例的行星际日冕物质抛射

K. Bryant, R. P. Young, H. LeFevre, C. Kuranz, J. Olson, K. McCollam, C. Forest
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摘要

太阳是一颗活跃的恒星,会爆发磁化等离子体,这些等离子体会到达地球,并在两极附近形成极光。这些爆发称为日冕物质抛射(CMEs),将等离子体和磁场送入太空。到达行星轨道的日冕物质抛射被称为行星际日冕物质抛射(ICMEs),它是地磁暴的来源之一,可以在有限的预警下对我们的现代电力系统造成重大破坏。为了研究日冕物质抛射的传播,我们利用威斯康星等离子体物理实验室的大红球(BRB)等离子体遏制装置设计了一个缩放实验。这些实验通过作为行星际介质的大红球内的环境等离子体,注入一个紧凑的等离子体环作为 ICME。磁场和温度探测器提供时间和空间的三维磁场信息,以及温度和密度与时间的函数关系。利用这些信息,我们可以确定紧凑环的特征,这些特征与真实的集成流体动力学事件中的特征一致。我们还确定了与集成流体器事件结构类似的冲击、鞘和喷出物。这项实验是为预测模型提供信息的第一步,它可以让我们有时间在强大的集成流体事件发生时保护我们的卫星和大型电力系统。
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Creating and studying a scaled interplanetary coronal mass ejection
The Sun, being an active star, undergoes eruptions of magnetized plasma that reach the Earth and cause the aurorae near the poles. These eruptions, called coronal mass ejections (CMEs), send plasma and magnetic fields out into space. CMEs that reach planetary orbits are called interplanetary coronal mass ejections (ICMEs) and are a source of geomagnetic storms, which can cause major damage to our modern electrical systems with limited warning. To study ICME propagation, we devised a scaled experiment using the Big Red Ball (BRB) plasma containment device at the Wisconsin Plasma Physics Laboratory. These experiments inject a compact torus of plasma as an ICME through an ambient plasma inside the BRB, which acts as the interplanetary medium. Magnetic and temperature probes provide three-dimensional magnetic field information in time and space, as well as temperature and density as a function of time. Using this information, we can identify features in the compact torus that are consistent with those in real ICMEs. We also identify the shock, sheath, and ejecta similar to the structure of an ICME event. This experiment acts as a first step to providing information that can inform predictive models, which can give us time to shield our satellites and large electrical systems in the event that a powerful ICME were to strike.
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