Basalt weathering rates on Earth and the duration of liquid water on the plains of Gusev Crater, Mars

Where Martian rocks have been exposed to liquid water, chemistry versus depth profiles could elucidate both Martian climate history and potential for life. The persistence of primary minerals in weathered profiles constrains the exposure time to liquid water: on Earth, mineral persistence times rang...

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Bibliographic Details
Published in:Geology (Boulder) 2008-01, Vol.36 (1), p.67-70
Main Authors: Hausrath, Elisabeth M, Navarre-Sitchler, Alexis K, Sak, Peter B, Steefel, Carl I, Brantley, Susan L
Format: Article
Language:English
Subjects:
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ANORTHOSITES
Arctic region
BASALT
basalts
Central America
chain silicates
CHEMISTRY
CLIMATES
computed tomography data
Costa Rica
craters
erosion
exposure age
Extraterrestrial geology
feldspar group
framework silicates
geochemistry
geochronology
Geological time
Geology
Gusev Crater
Igneous rocks
liquid phase
Mars
MARS PLANET
Minerals
nesosilicates
OLIVINE
olivine group
orthosilicates
plagioclase
plains
planets
pyroxene group
silicates
Soil erosion
Svalbard
terrestrial comparison
terrestrial planets
TRANSPORT
volcanic rocks
WATER
WEATHERING
weathering rates
weathering rinds
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Summary:Where Martian rocks have been exposed to liquid water, chemistry versus depth profiles could elucidate both Martian climate history and potential for life. The persistence of primary minerals in weathered profiles constrains the exposure time to liquid water: on Earth, mineral persistence times range from ∼10 k.y. (olivine) to ∼250 k.y. (glass) to ∼1 m.y. (pyroxene) to ∼5 m.y. (plagioclase). Such persistence times suggest mineral persistence minima on Mars. However, Martian solutions may have been more acidic than on Earth. Relative mineral weathering rates observed for basalt in Svalbard (Norway) and Costa Rica demonstrate that laboratory pH trends can be used to estimate exposure to liquid water both qualitatively (mineral absence or presence) and quantitatively (using reactive transport models). Qualitatively, if the Martian solution pH >∼2, glass should persist longer than olivine; therefore, persistence of glass may be a pH indicator. With evidence for the pH of weathering, the reactive transport code CrunchFlow can quantitatively calculate the minimum duration of exposure to liquid water consistent with a chemical profile. For the profile measured on the surface of the exposed Martian rock known as Humphrey in Gusev Crater, the calculated exposure time is 22 k.y., which is a minimum due to physical erosion. If correct, this estimate is consistent with short-term, episodic alteration accompanied by ongoing surface erosion. More of these depth profiles should be measured to illuminate the weathering history of Mars.
ISSN:0091-7613
1943-2682
DOI:10.1130/G24238A.1