Validity of the Apatite/Merrillite Relationship in Evaluating the Water Content in the Martian Mantle: Implications from Shergottite Northwest Africa (NWA) 2975

Phosphates from the Martian shergottite NWA 2975 were used to obtain insights into the source and subsequence differentiation of the melt/melts. The crystallization of two generations of fluorapatite (F > Cl~OH and F-rich), chlorapatite and ferromerrillite-merrillite were reconstructed from TEM (...

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Published inGeosciences (Basel) Vol. 7; no. 4; p. 99
Main Authors Słaby, Ewa, Förster, Hans-Jürgen, Wirth, Richard, Wudarska, Alicja, Birski, Łukasz, Moszumańska, Izabela
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.12.2017
Subjects
Apatite
chlorapatite
Crystallization
Crystals
Degassing
Differentiation
Earth
Earth science
Electron microscopy
EPMA
ferromerrillite
Fluids
Fluorapatite
Geochemistry
LA-ICP-MS
Lava
Magma
Mantle
Melts (crystal growth)
Moisture content
Phosphates
Planetary mantles
Rare earth elements
shergottite
TEM
Transmission electron microscopy
Volatiles
Water content
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Summary:Phosphates from the Martian shergottite NWA 2975 were used to obtain insights into the source and subsequence differentiation of the melt/melts. The crystallization of two generations of fluorapatite (F > Cl~OH and F-rich), chlorapatite and ferromerrillite-merrillite were reconstructed from TEM (Transmission Electron Microscopy) and geochemical analyses. The research results indicated that the recognized volatiles budget of the two generations of fluorapatite was related to their magmatic origin. The apatite crystals crystallized from an evolved magma during its final differentiation and degassing stage. In turn, chlorapatite replaced ferromerrillite-merrillite and was not related to, mantle-derived shergottite magma. The relationship between merrillite and apatite indicates that apatite is most probably a product of merrillite reacting with fluids. REE (rare earth elements) pattern of Cl-apatite might point to an origin associated with exogenous fluids mixed with fluids exsolved from evolved magma. The study shows that, among the three types of apatite, only the fluorapatite (F > Cl~OH) is a reliable source for assessing the degree of Martian mantle hydration. The occurrence of apatite with merrillite requires detailed recognition of their relationship. Consequently, the automatic use of apatite to assess the water content of the magma source can lead to false assumptions if the origin of the apatite is not precisely determined.
ISSN:2076-3263
2076-3263
DOI:10.3390/geosciences7040099