MESSENGER Observations of Planetary Ion Enhancements at Mercury's Northern Magnetospheric Cusp During Flux Transfer Event Showers

Sun, W.; Slavin, J. A.; Milillo, A.; Dewey, R. M.; Orsini, S.; Jia, Xianzhe; Raines, J. M.; Livi, S.; Jasinski, Jamie M.; Fu, S. Y.; Zhao, Jiutong; Zong, Qiugang; Saito, Yoshifumi; Li, Changkun

doi:10.1029/2022ja030280

Cited by 12 publications

(23 citation statements)

References 102 publications

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“…Using this method, the average estimated precipitation flux in orbit 3,795 is 2.9 × 10 7 cm −2 s −1 , and in orbit 3,807 is 4.8 × 10 7 cm −2 s −1 . These estimates are of the same order of magnitude as has been previously found for average proton precipitation in the northern dayside cusp (Raines et al, 2022), and about one order of magnitude less than the proton precipitation rate during active magnetopause reconnection intervals (Sun et al, 2022).…”

Section: Results: Precipitationsupporting

confidence: 85%

“…Because of the earlier‐mentioned recent finding that sodium may be more tightly bound to the surface than previously estimated (Morrissey et al., 2022), at least one widely used model does not anticipate that a highly variable process like ion sputtering (brought about by ion precipitation) could be a dominant source process for Mercury's more slowly varying exosphere (Killen et al., 2022), and that other processes like photon‐stimulated desorption (Cassidy et al., 2015) and micrometeoroid impacts (Cassidy et al., 2021; Jasinski et al., 2020) dominate. Notwithstanding that conclusion, recent analysis has also successfully shown that the cusp ion precipitation rate is well‐correlated with significant variability in the density of singly ionized sodium in Mercury's near space environment (Sun et al., 2022).…”

Section: Introductionmentioning

confidence: 99%

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Observations of Mercury's Plasma Sheet Horn: Characterization and Contribution to Proton Precipitation

et al. 2022

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The Mercury Surface, Space ENvironment, GEochemistry and Ranging (MESSENGER) spacecraft was the first spacecraft to orbit the planet Mercury. Previous analysis of MESSENGER data has established that of all the planets in the solar system, Mercury's magnetosphere is the most like Earth's, dominated by the Dungey cycle in its dynamic response of the magnetosphere to solar wind forcing. In this work, we identify and describe for the first time Mercury's northern plasma sheet horn—a Dungey cycle feature key to plasma precipitation. We find three possible geometries for potential horn observation by MESSENGER and describe a case study of each. Two additional case studies are presented with geometries particularly favorable to estimating plasma precipitation within the horns. Estimates of proton precipitation flux are performed, which show precipitation levels on the order of 107 per cm2 per second, on the same order of magnitude as the estimated proton precipitation flux in the dayside cusp despite the higher average energy of the protons in the horn. Potential paths for future study of the horns are discussed.

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Section: Results: Precipitationsupporting

confidence: 85%

Section: Introductionmentioning

confidence: 99%

Observations of Mercury's Plasma Sheet Horn: Characterization and Contribution to Proton Precipitation

et al. 2022

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“…2b. This result support the common assumption of negligible EII for the Na exosphere [16,35]. Nevertheless, compared to photoionization, EII should not be considered a secondary process for the H, He, O and Mn exosphere.…”

supporting

confidence: 83%

Solar-wind electron precipitation on weakly magnetized bodies: the planet Mercury

Lavorenti,

Henri,

Califano

et al. 2022

Preprint

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Mercury is the archetype of a weakly magnetized, airless, telluric body immersed in the solar wind. Due to the lack of any substantial atmosphere, the solar wind directly precipitates on Mercury's surface. Using a 3D fully-kinetic self-consistent plasma model, we show for the first time that solarwind electron precipitation drives (i) efficient ionization of multiple species (H, He, O and Mn) in Mercury's neutral exosphere and (ii) emission of X-rays from the planet's surface. This is the first, independent evidence of X-ray auroras on Mercury using a numerical approach.

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“…Flux transfer events (FTEs), a series of distinct bipolar perturbations in the magnetic field component normal to the planetary magnetopause, topologically connect the interplanetary and planetary magnetic fields in the magnetopause (Russell & Elphic 1978), and provide a channel for mass and energy from the solar wind to the planetary magnetosphere (Lockwood & Moen 1999;Paschmann et al 1982;Hasegawa et al 2006;Kuznetsova et al 2009;Tan et al 2011;Dong et al 2017;Sun et al 2022). It is generally believed that FTEs are essentially magnetic flux ropes formed in multiple X-line reconnection occurring in the magnetopause current sheet (Lee & Fu 1985;Zhong et al 2013;Fuselier et al 2018;Guo et al 2020).…”

Section: Introductionmentioning

confidence: 99%

“…During a typical FTE shower, each FTE has the duration of about 1-2 s, and the separation between two neighboring FTE centers is about 5-6 s (Sun et al 2020). An FTE shower can occur at the low-latitude dayside magnetopause when the IMF has a southward component, as well as at the high-latitude nightside magnetopause when the IMF has a northward component (Sun et al 2020;Zhong et al 2020;Sun et al 2022). Therefore, the properties of FTEs in Mercury's magnetopause are much different from those at Earth, where the duration of FTE ranges from about 1-2 minutes and the separation is about 8 minutes (Rijnbeek et al 1984).…”

Section: Introductionmentioning

confidence: 99%

Three-dimensional Global Hybrid Simulations of Flux Transfer Event Showers at Mercury

Guo

et al. 2022

ApJ

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One of the important MESSENGER observations is the formation of flux transfer event (FTE) showers, where tens of FTEs are observed in a short time interval of about 1–2 minutes, at Mercury’s magnetopause. In this paper, we investigate the interactions between the solar wind and Mercury’s magnetosphere using three-dimensional global hybrid simulations. When the interplanetary magnetic field (IMF) is purely southward, we can observe FTE showers at the low-latitude dayside magnetopause, and these FTEs can propagate northward or southward with a speed of about 90 km s−1. When the IMF is purely northward, FTE showers can be produced in both the northward and southward hemispheres of the high-latitude nightside magnetopause, and these FTEs propagate toward the magnetotail with a speed of about 250 km s−1. The typical FTEs have a duration of 1–2 s, and reoccur in 5–6 s. Our simulations provide a good explanation for FTE showers observed by MESSENGER.

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MESSENGER Observations of Planetary Ion Enhancements at Mercury's Northern Magnetospheric Cusp During Flux Transfer Event Showers

Cited by 12 publications

References 102 publications

Observations of Mercury's Plasma Sheet Horn: Characterization and Contribution to Proton Precipitation

Observations of Mercury's Plasma Sheet Horn: Characterization and Contribution to Proton Precipitation

Solar-wind electron precipitation on weakly magnetized bodies: the planet Mercury

Three-dimensional Global Hybrid Simulations of Flux Transfer Event Showers at Mercury

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