Energetic electron observations by parker solar Probe/IS circle dot IS during the first widespread SEP event of solar cycle 25 on 2020 november 29. Mitchell, J. G., Nolfo, G. A. D., Hill, M. E., Christian, E. R., Richardson, I. G., McComas, D. J., Jr. McNutt, R. L., Mitchell, D. G., Schwadron, N. A., Bale, S. D., Giacalone, J., Joyce, C. J., Niehof, J. T., & Szalay, J. R. Astrophysical Journal, 2021. Publisher: Iop Publishing Ltd Type: Article tex.date-modified: 2022-04-12 11:34:55 +0100
Energetic electron observations by parker solar Probe/IS circle dot IS during the first widespread SEP event of solar cycle 25 on 2020 november 29 [link]Paper  doi  abstract   bibtex   
At the end of 2020 November, two coronal mass ejections (CMEs) erupted from the Sun and propagated through the interplanetary medium in the direction of Parker Solar Probe while the spacecraft was located at similar to 0.81 au. The passage of these interplanetary CMEs (ICMEs) starting on November 29 (DOY 334) produced the largest enhancement of energetic ions and electrons observed by the Integrated Science Investigation of the Sun (IS circle dot IS) energetic particle instrument suite on board Parker Solar Probe during the mission's first eight orbits. This was also the first spatially widespread solar energetic particle event observed in solar cycle 25. We investigate several key characteristics of the energetic electron event including the time profile and anisotropy distribution of near-relativistic electrons as measured by IS circle dot IS's low-energy Energetic Particle Instrument (EPI-Lo) and compare these observations with contextual data from the Parker Solar Probe Fields Experiment magnetometer. These are the first electron anisotropy measurements from IS circle dot IS/EPI-Lo, demonstrating that the instrument can successfully produce these measurements. We find that the electron count rate peaks at the time of the shock driven by the faster of the two ICMEs, implying that the shock parameters of this ICME are conducive to the acceleration of electrons. Additionally, the angular distribution of the electrons during the passage of the magnetic clouds associated with the ICMEs shows significant anisotropy, with electrons moving primarily parallel and antiparallel to the local magnetic field as well as bidirectionally, providing an indication of the ICME's magnetic topology and connectivity to the Sun or magnetic structures in the inner heliosphere.
@article{Mitchell2021,
	title = {Energetic electron observations by parker solar {Probe}/{IS} circle dot {IS} during the first widespread {SEP} event of solar cycle 25 on 2020 november 29},
	volume = {919},
	issn = {0004-637X},
	url = {https://doi.org/10.3847/1538-4357/ac110e},
	doi = {10.3847/1538-4357/ac110e},
	abstract = {At the end of 2020 November, two coronal mass ejections (CMEs) erupted from the Sun and propagated through the interplanetary medium in the direction of Parker Solar Probe while the spacecraft was located at similar to 0.81 au. The passage of these interplanetary CMEs (ICMEs) starting on November 29 (DOY 334) produced the largest enhancement of energetic ions and electrons observed by the Integrated Science Investigation of the Sun (IS circle dot IS) energetic particle instrument suite on board Parker Solar Probe during the mission's first eight orbits. This was also the first spatially widespread solar energetic particle event observed in solar cycle 25. We investigate several key characteristics of the energetic electron event including the time profile and anisotropy distribution of near-relativistic electrons as measured by IS circle dot IS's low-energy Energetic Particle Instrument (EPI-Lo) and compare these observations with contextual data from the Parker Solar Probe Fields Experiment magnetometer. These are the first electron anisotropy measurements from IS circle dot IS/EPI-Lo, demonstrating that the instrument can successfully produce these measurements. We find that the electron count rate peaks at the time of the shock driven by the faster of the two ICMEs, implying that the shock parameters of this ICME are conducive to the acceleration of electrons. Additionally, the angular distribution of the electrons during the passage of the magnetic clouds associated with the ICMEs shows significant anisotropy, with electrons moving primarily parallel and antiparallel to the local magnetic field as well as bidirectionally, providing an indication of the ICME's magnetic topology and connectivity to the Sun or magnetic structures in the inner heliosphere.},
	number = {2},
	journal = {Astrophysical Journal},
	author = {Mitchell, J. G. and Nolfo, G. A. De and Hill, M. E. and Christian, E. R. and Richardson, I. G. and McComas, D. J. and Jr. McNutt, R. L. and Mitchell, D. G. and Schwadron, N. A. and Bale, S. D. and Giacalone, J. and Joyce, C. J. and Niehof, J. T. and Szalay, J. R.},
	year = {2021},
	note = {Publisher: Iop Publishing Ltd
Type: Article
tex.date-modified: 2022-04-12 11:34:55 +0100},
}

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