Abstract
The Lafayette meteorite is an olivine clinopyroxenite that crystallized on Mars ∼1300million years ago within a lava flow or shallow sill. Liquid water entered this igneous rock ∼700million years later to produce a suite of secondary minerals, collectively called ‘iddingsite’, that occur as veins within grains of augite and olivine. The deuterium/hydrogen ratio of water within these secondary minerals shows that the aqueous solutions were sourced from one or more near-surface reservoirs. Several petrographically distinct types of veins can be recognised by differences in their width, shape, and crystallographic orientation. Augite and olivine both contain veins of a very fine grained hydrous Fe- and Mg-rich silicate that are ∼1–2μm in width and lack any preferred crystallographic orientation. These narrow veins formed by cementation of pore spaces that had been opened by fracturing and probably in response to shock. The subset of olivine-hosted veins whose axes lie parallel to (001) have serrated walls, and formed by widening of the narrow veins by interface coupled dissolution–precipitation. Widening started by replacement of the walls of the narrow precursor veins by Fe–Mg silicate, and a crystallographic control on the trajectory of the dissolution–precipitation front created micrometre-scale {111} serrations. The walls of many of the finely serrated veins were subsequently replaced by siderite, and the solutions responsible for carbonation of olivine also partially recrystallized the Fe–Mg silicate. Smectite was the last mineral to form and grew by replacement of siderite. This mineralization sequence shows that Lafayette was exposed to two discrete pulses of aqueous solutions, the first of which formed the Fe–Mg silicate, and the second mediated replacement of vein walls by siderite and smectite. The similarity in size, shape and crystallographic orientation of iddingsite veins in the Lafayette meteorite and in terrestrial basalts demonstrates a common microstructural control on water–mineral interaction between Mars and Earth, and indicates that prior shock deformation was not a prerequisite for aqueous alteration of the martian crust.
Highlights
The nakhlite meteorites are cumulate clinopyroxenites (Bunch and Reid, 1975; Friedman-Lentz et al, 1999; Treiman, 2005) that are believed to originate from the same igneous body on Mars, either a lava flow or shallow sill (Treiman, 1986; Friedman-Lentz et al, 1999; Mikouchi et al, 2006, 2012)
Backscattered electron (BSE) images and qualitative Xray spot analyses were obtained from these samples after carbon coating and using two field-emission SEMs, both operated at 20 kV: a FEI Quanta 200F equipped with an EDAX Genesis energy-dispersive X-ray (EDX) analysis system, and a Zeiss Sigma equipped with an Oxford Instruments Aztec EDX analysis system
Petrographic evidence shows that some of these fractures predate the precipitation of secondary minerals, whereas others must have formed after aqueous activity because they cross-cut the veins
Summary
The nakhlite meteorites are cumulate clinopyroxenites (Bunch and Reid, 1975; Friedman-Lentz et al, 1999; Treiman, 2005) that are believed to originate from the same igneous body on Mars, either a lava flow or shallow sill (Treiman, 1986; Friedman-Lentz et al, 1999; Mikouchi et al, 2006, 2012) This cogenetic model is supported by their common ages of crystallization (Amazonian, 1327 ± 39 Ma; Borg and Drake, 2005 and references therein) and ejection ($11 Ma; Eugster et al, 1997). The Lafayette meteorite has been selected for study because it has the highest water content amongst the nakhlites (0.373–0.387 wt.%; Karlsson et al, 1992; Leshin et al, 1996), and its iddingsite veins are correspondingly the widest and most mineralogically diverse within the group (Changela and Bridges, 2011)
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