利用 INFROS 模拟不同日心距离行星际日冕物质抛射的磁矢量

Ranadeep Sarkar, Nandita Srivastava, Nat Gopalswamy and Emilia Kilpua
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摘要

行星际磁通量模拟器(INFROS)是一个受观测约束的分析模型,专门用于预测行星际日冕物质抛射(ICMEs)所蕴含的磁场南向分量(Bz)的强度。在这项工作中,我们对两个位于不同日心距离的径向排列航天器先后观测到的六个日冕物质抛射事件验证了这一模型。本研究选取的六个日冕物质抛射(ICMEs)包括与孤立的日冕物质抛射(CMEs)演化相关的案例,以及与高速流(HSSs)和高密度流(HDSs)相互作用的案例。对于孤立的日冕物质抛射,我们的结果表明两个航天器的模型输出与现场观测结果非常吻合。然而,对于大多数相互作用的事件,模型只在内部航天器上正确捕捉到了CME的演变过程。由于与 HSSs 和 HDSs 的相互作用(大多数情况下发生在内部航天器以外的日心距离),ICME 演变不再保持自相似性。因此,该模型低估了外层航天器的场强。我们的研究结果表明,利用内航天器观测数据对 INFROS 模型进行约束,可以显著提高对三个自相似膨胀事件的外航天器预测精度,使观测到的 Bz 曲线与预测的 Bz 曲线之间的相关性达到 90%。这项工作还对可能导致恶劣空间天气的相互作用引起的集成电路小型粒子磁场增强进行了定量估算。我们的结论是,根据遥感观测结果,自相似膨胀假设为任何日心距离上的磁场强度估算提供了一个下限。
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Modeling the Magnetic Vectors of Interplanetary Coronal Mass Ejections at Different Heliocentric Distances with INFROS
The INterplanetary Flux ROpe Simulator (INFROS) is an observationally constrained analytical model dedicated to forecasting the strength of the southward component (Bz) of the magnetic field embedded in interplanetary coronal mass ejections (ICMEs). In this work, we validate the model for six ICMEs sequentially observed by two radially aligned spacecraft positioned at different heliocentric distances. The six selected ICMEs in this study comprise cases associated with isolated coronal mass ejection (CME) evolution as well as those interacting with high-speed streams (HSSs) and high-density streams (HDSs). For the isolated CMEs, our results show that the model outputs at both spacecraft are in good agreement with in situ observations. However, for most of the interacting events, the model correctly captures the CME evolution only at the inner spacecraft. Due to the interaction with HSSs and HDSs, which in most cases occurred at heliocentric distances beyond the inner spacecraft, the ICME evolution no longer remains self-similar. Consequently, the model underestimates the field strength at the outer spacecraft. Our findings indicate that constraining the INFROS model with inner-spacecraft observations significantly enhances the prediction accuracy at the outer spacecraft for the three events undergoing self-similar expansion, achieving a 90% correlation between observed and predicted Bz profiles. This work also presents a quantitative estimation of the ICME magnetic field enhancement due to interaction which may lead to severe space weather. We conclude that the assumption of self-similar expansion provides a lower limit to the magnetic field strength estimated at any heliocentric distance, based on the remote-sensing observations.
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