http://arxiv.org/abs/2012.07456
On April 19th 2020 a CME was detected in-situ by Solar Orbiter at a heliocentric distance of about 0.8 AU. The CME was later observed in-situ on April 20th by the Wind and BepiColombo spacecraft whilst BepiColombo was located very close to Earth. This CME presents a good opportunity for a triple radial alignment study, as the spacecraft were separated by less than 5$^\circ$ in longitude. The source of the CME, which was launched on April 15th, was an almost entirely isolated streamer blowout. STEREO-A observed the event remotely from -75.1$^\circ$ longitude: an exceptionally well suited viewpoint for heliospheric imaging of an Earth directed CME. The configuration of the four spacecraft has provided an exceptionally clean link between remote imaging and in-situ observations of the CME. We have used the in-situ observations of the CME at Solar Orbiter, Wind and BepiColombo, and the remote observations of the CME at STEREO-A in combination with flux rope models to determine the global shape of the CME and its evolution as it propagated through the inner heliosphere. A clear flattening of the CME cross-section has been observed by STEREO-A, and further confirmed by comparing profiles of the flux rope models to the in-situ data, where the distorted flux rope cross-section qualitatively agrees most with in-situ observations of the magnetic field at Solar Orbiter. Comparing in-situ observations of the magnetic field between spacecraft, we find that the dependence of the maximum (mean) magnetic field strength decreases with heliocentric distance as $r^{-1.22 \pm 0.42}$ ($r^{-1.10 \pm 0.20}$), in disagreement with previous studies. Further assessment of the axial and poloidal magnetic field strength dependencies suggests that the expansion of the CME is likely neither self-similar nor cylindrically symmetric.
E. Davies, C. Möstl, M. Owens, et. al.
Tue, 15 Dec 20
47/136
Comments: N/A