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1 Sciences and Exploration Directorate
NASA Goddard Space Flight
Center
Greenbelt, MD 20771, USA
E-mail:
laurie.leshin{at}nasa.gov
2 Department of Mineral Sciences
National Museum of National
History
Smithsonian Institution
Washington, DC 20560, USA
E-mail:
vicenzi{at}volcano.si.edu
Martian meteorites have delivered to Earth water molecules and minerals produced by aqueous processes on Mars. The study of these samples, using powerful analytical instrumentation, provides a basis for understanding aqueous activity on Mars. Although most analyses are at the scale of microns, the conclusions reached have important implications for large-scale aqueous processes. Secondary minerals, such as clays, salts, and carbonates, are present at some level in all Martian meteorite subtypes and are especially important in the nakhlites and ALH84001. Light element stable isotope analyses show evidence for mixing between atmosphere and magmatic fluids into a crustal reservoir, and that this crustal water was not in equilibrium with the host rocks. The mineralogical and isotopic data present a fairly consistent picture of the aqueous history of Mars: low levels of aqueous alteration are generally present but extensive aqueous processes are probably limited in space and time.
KEYWORDS: Mars, meteorites, stable isotopes, carbonates, water-rock interaction
This article has been cited by other articles:
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  A. A. Olsen and J. D. Rimstidt Using a mineral lifetime diagram to evaluate the persistence of olivine on Mars American Mineralogist, April 1, 2007; 92(4): 598 - 602. [Abstract] [Full Text] [PDF]
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