Statistical Study of Mercury's Energetic Electron Events as Observed by the Gamma‐Ray and Neutron Spectrometer Instrument Onboard MESSENGER

Nikoukar, Romina; Lawrence, D. J.; Peplowski, P. N.; Dewey, R. M.; Korth, H.; Baker, D. N.; McNutt, R. L.

doi:10.1029/2018ja025339

Cited by 4 publications

(5 citation statements)

References 33 publications

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“…Furthermore, as dipolarizations and flux ropes interact with the surrounding plasma environment, they generate additional asymmetries in the magnetotail, including en- ergetic electron injections, fast sunward flows, magnetic pileup, and substorm current wedge formation. Dipolarizations, for example, are a dominant source of energetic electron acceleration within Mercury's magnetosphere (Dewey et al, 2017), resulting in energetic electron injections to be more frequent at dawn than at dusk (Baker et al, 2016), independent of electrons' eastward drift about the planet (Walsh et al, 2013;Nikoukar et al, 2018;Dong et al, 2019). A fraction of these energetic electrons precipitate to the planet, and in the absence of a thick atmosphere, collide with the planet's surface to produce X-ray fluorescence and space weathering (Starr et al, 2012).…”

Section: Magnetotail Reconnection Dynamicsmentioning

confidence: 99%

Review of Mercury’s dynamic magnetosphere: Post-MESSENGER era and comparative magnetospheres

Sun

Dewey

Aizawa

et al. 2021

Sci. China Earth Sci.

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This review paper summarizes the research of Mercury’s magnetosphere in the Post-MESSENGER era and compares its dynamics to those in other planetary magnetospheres, especially to those in Earth’s magnetosphere. This review starts by introducing the planet Mercury, including its interplanetary environment, magnetosphere, exosphere, and conducting core. The frequent and intense magnetic reconnection on the dayside magnetopause, which is represented by the flux transfer event “shower”, is reviewed on how they depend on magnetosheath plasma β and magnetic shear angle across the magnetopause, following by how it contributes to the flux circulation and magnetosphere-surface-exosphere coupling. In the next, Mercury’s magnetosphere under extreme solar events, including the core induction and the reconnection erosion on the dayside magnetosphere, the responses of the nightside magnetosphere, are reviewed. Then, the dawn-dusk properties of the plasma sheet, including the features of the ions, the structure of the current sheet, and the dynamics of magnetic reconnection, are summarized. The last topic is devoted to the particle energization in Mercury’s magnetosphere, which includes the energization of the Kelvin-Helmholtz waves on the magnetopause boundaries, reconnection-generated magnetic structures, and the cross-tail electric field. In each chapter, the last section discusses the open questions related to each topic, which can be considered by the simulations and the future spacecraft mission. We end this paper by summarizing the future BepiColombo opportunities, which is a joint mission of ESA and JAXA and is en route to Mercury.

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Section: Magnetotail Reconnection Dynamicsmentioning

confidence: 99%

Review of Mercury’s dynamic magnetosphere: Post-MESSENGER era and comparative magnetospheres

Sun

Dewey

Aizawa

et al. 2021

Sci. China Earth Sci.

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“…Following earlier studies (Lawrence et al, 2013(Lawrence et al, , 2017, the duration of these events was determined manually by looking through the spectra for increased background (see the list of SEP events given in Lawrence et al, 2016). Similarly, those data acquired during energetic electron events (EEEs; Lawrence, Anderson, et al, 2015;Nikoukar et al, 2018) were also removed as they complicate the derivation of neutron count rates. This removal of EEEs resulted in the loss of just a few spectra per orbit.…”

Section: Messenger Epithermal Neutron Data Set Cutsmentioning

confidence: 99%

MESSENGER Gamma Ray Spectrometer and Epithermal Neutron Hydrogen Data Reveal Compositional Differences Between Mercury's Hot and Cold Poles

et al. 2019

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The presence of hydrogen, most likely in the form of water ice, is well established in Mercury's permanently shaded polar craters. But lower concentrations that may exist away from the poles have not previously been well constrained. In this work we use data from the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) Gamma‐Ray and Neutron Spectrometer to produce the first map of the absolute hydrogen abundance in Mercury's northern hemisphere. We find a mean abundance of ppm and a latitudinal trend that agrees with earlier results showing enhanced hydrogen contained within Mercury's radar bright craters. Additionally, we observe a middle‐ and low‐latitude variation in hydrogen abundance that is correlated most strongly with temperature 20 cm beneath Mercury's surface.

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“…In the tentative energetic electron enhancement events at Mercury, energetic electrons have a pancake PAD mostly distributed at 90 deg. based on the MESSENGER observations (Ho et al., 2011; Nikoukar et al., 2018). Our simulations also reconstruct the pancake PAD and show that the tentative energetic electron enhancements can evolve to a flattop PAD with repetitive chorus generation at Mercury, because the resonant electrons are effectively accelerated in the same manner as in the Earth’s radiation belt (Hikishima et al., 2009).…”

Section: Discussionmentioning

confidence: 99%

“…To validate the chorus wave generation in the day and night sectors and the contribution of evolution of PAD of energetic electrons via wave–particle interactions for the observation results showing the mainly 90‐deg. PAD (Ho et al., 2011; Nikoukar et al., 2018), we conducted a one‐dimensional full particle‐in‐cell (PIC) simulation along a magnetic field line in the Mercury magnetospheric environment. The PIC simulation is based on previous works on chorus emission waves in the Earth’s inner magnetosphere (Hikishima et al., 2009), but the parameters are widely different from the typical values used for the Earth (e.g., higher f p / f c , lower initial hot electron velocity, highly stretched field line, larger loss cone, etc.).…”

Section: Simulationsmentioning

confidence: 99%

“…The most burst events show dominantly a 90‐deg. pitch angle distribution (PAD) (Nikoukar et al., 2018), and the mechanisms for forming such a PAD are not fully understood. The origin of these electron burst events and understanding the similarity and the difference in the behavior of electron dynamics between Mercury’s and Earth’s magnetospheres may elucidate particle acceleration mechanisms underlying in our Solar Systems.…”

Section: Introductionmentioning

confidence: 99%

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Possible Global Generation Region of Nonlinear Whistler‐Mode Chorus Emission Waves at Mercury

Ozaki,

Kondo,

Yagitani

et al. 2024

JGR Space Physics

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Chorus waves are a kind of intense electromagnetic emission wave in magnetized planets and can play important roles in the kinetic electron dynamics in planetary magnetospheres. Rapid changes of the ring electron current belt in Mercury’s magnetosphere and the contribution of chorus waves have remained long‐standing scientific issues from the first Mercury flyby observations by Mariner 10 in 1970s because of the small size of the magnetosphere. Based on theoretical analyses and simulations successfully reconstructing Earth’s chorus wave properties, we report on possible generation regions of chorus waves in Mercury’s magnetosphere. The theoretical analysis for low‐temperature‐anisotropy electrons shows a clear asymmetric day–night spatial distribution of the possible chorus generation region because of the difference in the nonlinear convective wave growth along the magnetic field lines. Simulation results show a rapid enhancement of the ring electron current belt by resonant interactions with repetitive chorus waves. Our study suggests that energetic electrons in Mercury’s magnetosphere can be enhanced locally by nonlinear chorus wave–particle interactions.

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Statistical Study of Mercury's Energetic Electron Events as Observed by the Gamma‐Ray and Neutron Spectrometer Instrument Onboard MESSENGER

Cited by 4 publications

References 33 publications

Review of Mercury’s dynamic magnetosphere: Post-MESSENGER era and comparative magnetospheres

Review of Mercury’s dynamic magnetosphere: Post-MESSENGER era and comparative magnetospheres

MESSENGER Gamma Ray Spectrometer and Epithermal Neutron Hydrogen Data Reveal Compositional Differences Between Mercury's Hot and Cold Poles

Possible Global Generation Region of Nonlinear Whistler‐Mode Chorus Emission Waves at Mercury

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