Coronal mass ejections observed by heliospheric imagers at 0.2 and 1 au

arXiv: Solar and Stellar Astrophysics Pub Date : 2020-11-10 DOI:10.1051/0004-6361/202039490

C. R. Braga, A. Vourlidas

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引用次数: 9

Abstract

Context. We study two coronal mass ejections (CMEs) observed between April 1-2, 2019 by both the inner Wide-Field Imager for Parker Solar Probe (WISPR-I) and the inner heliospheric imager (HI-1) on board STEREO-A. This is the first study of CME observations from two viewpoints in similar directions but at considerably different solar distances. Aims. Our objective is to understand how the PSP observations affect the CME kinematics, especially due to its proximity to the Sun. Methods. We estimate the CME positions, speeds, accelerations, propagation directions and longitudinal deflections using imaging observations from two spacecraft, and a set of analytical expressions that consider the CME as a point structure and take into account the rapid change in spacecraft position. Results. We find that both CMEs are slow ($< 400\ km\ s^{-1}$), propagating eastward of the Sun-Earth line. The second CME seems to accelerate between $\sim 0.1$ to $\sim 0.2\ au$ and deflect westward with an angular speed consistent with the solar rotation speed. We find some discrepancies in the CME solar distance (up to $0.05\ au$, particularly for CME \#1), latitude (up to $\sim10^{\circ}$) and longitude (up to $24^{\circ}$) when comparing results from different fit cases (different observations or set of free parameters). Conclusions. Discrepancies in longitude are likely due to the feature tracked visually rather than instrumental biases or fit assumptions. For similar reasons, the CME \#1 solar distance, as derived from WISPR-I observations, is larger than the HI-1 result, regardless of the fit parameters considered. Error estimates for CME kinematics do not show any clear trend associated to the observing instrument. The source region location and the lack of any clear in situ counterparts (both at near-Earth and at PSP) support our estimate of the propagation direction for both events.

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日冕物质抛射由日球层成像仪在0.2和1au观测

上下文。我们研究了2019年4月1日至2日由帕克太阳探测器内宽视场成像仪(wisr - i)和STEREO-A上的内日光层成像仪(HI-1)观测到的两次日冕物质抛射(cme)。这是第一次从两个视点在相似的方向观测日冕物质抛射，但在相当不同的太阳距离。目标我们的目标是了解PSP观测如何影响CME的运动学，特别是由于它靠近太阳。方法。我们利用两个航天器的成像观测数据，以及考虑到航天器位置快速变化的CME作为点结构的一组解析表达式，估计了CME的位置、速度、加速度、传播方向和纵向偏转。结果。我们发现两个日冕物质抛射都是缓慢的($< 400\ km\ s^{-1}$)，沿日地线向东传播。第二次日冕物质抛射似乎在$\sim 0.1$到$\sim 0.2 $ au之间加速，并以与太阳自转速度一致的角速度向西偏转。当比较不同拟合情况(不同观测或一组自由参数)的结果时，我们发现CME太阳距离(高达$0.05\ au$，特别是CME \#1)，纬度(高达$\sim10^{\circ}$)和经度(高达$24^{\circ}$)存在一些差异。结论。经度上的差异很可能是由于视觉追踪的特征，而不是工具偏差或拟合假设。由于类似的原因，从wispr -1观测得到的CME \#1太阳距离大于HI-1的结果，而不考虑拟合参数。CME运动学的误差估计没有显示任何与观测仪器相关的明确趋势。震源区域的位置和缺乏任何明确的原位对应(近地和PSP)支持我们对这两个事件的传播方向的估计。

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arXiv: Solar and Stellar Astrophysics

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