Evidence for geochemical terranes on Mercury: Global mapping of major elements with MESSENGER's X-Ray Spectrometer

Evidence for geochemical terranes on Mercury: Global mapping of major elements with MESSENGER's X-Ray Spectrometer

We have mapped the major-element composition of Mercury's surface from orbital MESSENGER X-Ray Spectrometer measurements. These maps constitute the first global-scale survey of the surface composition of a Solar System body conducted with the technique of planetary X-ray fluorescence. Full maps...

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Veröffentlicht in:Earth and planetary science letters 2015-04, Vol.416, p.109-120
Hauptverfasser: Weider, Shoshana Z., Nittler, Larry R., Starr, Richard D., Crapster-Pregont, Ellen J., Peplowski, Patrick N., Denevi, Brett W., Head, James W., Byrne, Paul K., Hauck, Steven A., Ebel, Denton S., Solomon, Sean C.
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Sprache:eng
Schlagworte:
Aluminum
Geochemistry
Magnesium
Mercury
Mercury surface
MESSENGER
Silicon
Solar system
Spectrometers
spectroscopy
X-ray fluorescence
X-rays
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container_end_page 120
container_issue
container_start_page 109
container_title Earth and planetary science letters
container_volume 416
creator Weider, Shoshana Z.
Nittler, Larry R.
Starr, Richard D.
Crapster-Pregont, Ellen J.
Peplowski, Patrick N.
Denevi, Brett W.
Head, James W.
Byrne, Paul K.
Hauck, Steven A.
Ebel, Denton S.
Solomon, Sean C.
description We have mapped the major-element composition of Mercury's surface from orbital MESSENGER X-Ray Spectrometer measurements. These maps constitute the first global-scale survey of the surface composition of a Solar System body conducted with the technique of planetary X-ray fluorescence. Full maps of Mg and Al, together with partial maps of S, Ca, and Fe, each relative to Si, reveal highly variable compositions (e.g., Mg/Si and Al/Si range over 0.1–0.8 and 0.1–0.4, respectively). The geochemical variations that we observe are consistent with those inferred from other MESSENGER geochemical remote sensing datasets, but they do not correlate well with units mapped previously from spectral reflectance or morphology. Location-dependent, rather than temporally evolving, partial melt sources were likely the major influence on the compositions of the magmas that produced different geochemical terranes. A large (>5×106 km2) region with the highest Mg/Si, Ca/Si, and S/Si ratios, as well as relatively thin crust, may be the site of an ancient and heavily degraded impact basin. The distinctive geochemical signature of this region could be the consequence of high-degree partial melting of a reservoir in a vertically heterogeneous mantle that was sampled primarily as a result of the impact event. •MESSENGER X-ray Spectrometer data used to produce global Mg/Si and Al/Si maps.•Major-element variations define large-scale geochemical terranes on Mercury.•Chemical heterogeneities do not match units mapped from morphology and color.•A heterogeneous mantle likely gave rise to the surface compositional variations.
doi_str_mv 10.1016/j.epsl.2015.01.023
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language eng
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subjects Aluminum
Geochemistry
Magnesium
Mercury
Mercury surface
MESSENGER
Silicon
Solar system
Spectrometers
spectroscopy
X-ray fluorescence
X-rays
title Evidence for geochemical terranes on Mercury: Global mapping of major elements with MESSENGER's X-Ray Spectrometer
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