MESSENGER detection of electron‐induced X‐ray fluorescence from Mercury's surface

Starr, R.; Schriver, D.; Nittler, L. R.; Weider, S. Z.; Byrne, P. K.; Ho, G. C.; Rhodes, E. A.; Schlemm, C. E.; Solomon, Sean C.; Trávníček, Pavel

doi:10.1029/2012je004118

Cited by 50 publications

(43 citation statements)

References 41 publications

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“…These observations suggest that the electrons could drift in longitude along closed field lines, as demonstrated in a few cases at higher energies by echoes [ Baker et al , ], and that there could be quasi‐trapped electrons in orbits close to Mercury's magnetic equator as a more or less standard feature. We refer to these particles as quasi‐trapped because most of the electrons at these energies (~ keV) cannot completely drift around the planet before either striking the surface or hitting the dayside magnetopause, and only a few make a complete orbit around the planet [ Schriver et al , ; Starr et al , ]. However, the fact that we detected these electrons on almost every orbit indicates that they represent a semipermanent feature.…”

Section: Discussion and Summarymentioning

confidence: 96%

MESSENGER observations of suprathermal electrons in Mercury's magnetosphere

Starr

Krimigis

et al. 2016

Geophysical Research Letters

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The X‐Ray Spectrometer (XRS) on the MErcury Surface, Space ENvironment, GEochemistry, and Ranging spacecraft regularly detected fluorescent X‐rays near Mercury induced by low‐energy (1–10 keV) or suprathermal electrons. We devised an algorithm to select these events from XRS records between April 2011 and March 2015 on the basis of their duration, location, and spectral slope. We identified 3102 events during 3900 orbits around Mercury, sampling all Mercury longitudes multiple times over the 4 year period. These suprathermal electrons were present near the planet at all local times, but the majority were on the nightside of the planet, and a dawn‐dusk asymmetry is seen in the data. When the event locations are plotted in a coordinate system based on a simplified magnetic field model, several distinct clusters of events are evident. We infer that all are signatures of accelerated electrons that were injected from Mercury's tail region to form a quasi‐trapped electron population at Mercury.

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Section: Discussion and Summarymentioning

confidence: 96%

MESSENGER observations of suprathermal electrons in Mercury's magnetosphere

Starr

Krimigis

et al. 2016

Geophysical Research Letters

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“…Do these measurements provide additional evidence for particle loss at Mercury's surface associated with its asymmetric magnetic field, as suggested by Korth et al . [], and as shown with measurements of electron‐induced X‐ray fluorescence [ Starr et al ., ]?…”

Section: Summary and Future Workmentioning

confidence: 99%

Comprehensive survey of energetic electron events in Mercury's magnetosphere with data from the MESSENGER Gamma‐Ray and Neutron Spectrometer

et al. 2015

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Data from the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) Gamma-Ray and Neutron Spectrometer have been used to detect and characterize energetic electron (EE) events in Mercury's magnetosphere. This instrument detects EE events indirectly via bremsstrahlung photons that are emitted when instrument and spacecraft materials stop electrons having energies of tens to hundreds of keV. From Neutron Spectrometer data taken between 18 March 2011 and 31 December 2013 we have identified 2711 EE events. EE event amplitudes versus energy are distributed as a power law and have a dynamic range of a factor of 400. The duration of the EE events ranges from tens of seconds to nearly 20 min. EE events may be classified as bursty (large variation with time over an event) or smooth (small variation). Almost all EE events are detected inside Mercury's magnetosphere on closed field lines. The precise occurrence times of EE events are stochastic, but the events are located in well-defined regions with clear boundaries that persist in time and form what we call "quasi-permanent structures." Bursty events occur closer to dawn and at higher latitudes than smooth events, which are seen near noon-to-dusk local times at lower latitudes. A subset of EE events shows strong periodicities that range from hundreds of seconds to tens of milliseconds. The few-minute periodicities are consistent with the Dungey cycle timescale for the magnetosphere and the occurrence of substorm events in Mercury's magnetotail region. Shorter periods may be related to phenomena such as north-south bounce processes for the energetic electrons.

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“…Closer examination reveals that these events are short, with durations equal to or less than the instrument integration period (3 s). This group of events could be related to the low‐energy, low‐intensity X‐ray fluorescence events observed during MESSENGER's low‐latitude flybys [ Ho et al , 2011a] and seen near the planet from orbital XRS observations [ Starr et al , 2012]. Prompted by the low‐energy electron (1–10 keV) events seen during the flybys, Schriver et al [2011] reported kinetic simulation results that suggested a quasi‐trapped population of low‐energy (1–10 keV) ions and electrons near Mercury's equatorial region.…”

Section: Statistical Analysis Of Energetic Electron Bursts At Mercurymentioning

confidence: 99%

Spatial distribution and spectral characteristics of energetic electrons in Mercury's magnetosphere

Krimigis

Gold

et al. 2012

J. Geophys. Res.

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[1] The Energetic Particle Spectrometer (EPS) on the MESSENGER spacecraft, in orbit about Mercury since March 2011, has detected bursts of low-and moderate-energy (tens to hundreds of keV) electrons during portions of most orbits. There have been periods when such bursts were observed regularly on every orbit over a span of several weeks, and other periods when electrons were not observed for several days at a time. We have systematically characterized these energetic events on the basis of particle intensity over the 12-month period since MESSENGER began orbital operations. Now that MESSENGER has sampled most Mercury longitudes and local times, it is evident that the largest burst events were either at high northern latitudes or near local midnight. Lower-energy events were also seen near the equator but were mostly absent in both the dawn and dusk local time sectors. The high-latitude and nightside events are similar in particle intensity, spectra, and pitch angle and are interpreted to be the result of acceleration by the same mechanism. Another group of events occurred upstream of Mercury's bow shock. For two examples of this group of upstream events with good pitch angle coverage, the particles were field-aligned and traveling away from the bow shock. This group of events is interpreted to be similar to upstream events found at Earth during which particles are accelerated at the bow shock and subsequently travel upstream into the solar wind.

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MESSENGER detection of electron‐induced X‐ray fluorescence from Mercury's surface

Cited by 50 publications

References 41 publications

MESSENGER observations of suprathermal electrons in Mercury's magnetosphere

MESSENGER observations of suprathermal electrons in Mercury's magnetosphere

Comprehensive survey of energetic electron events in Mercury's magnetosphere with data from the MESSENGER Gamma‐Ray and Neutron Spectrometer

Spatial distribution and spectral characteristics of energetic electrons in Mercury's magnetosphere

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