Experimental evidence of fast transport of trace elements in planetary basaltic crusts by high temperature metamorphism

Experimental evidence of fast transport of trace elements in planetary basaltic crusts by high temperature metamorphism

Incompatible elements (IEs) such as K, P, Ti, and rare earth elements (REEs) provide important constraints on the geochemistry and chronology of basaltic meteorites, most of which experienced complicated post-crystallization histories. These elements are immobile under subsolidus conditions because...

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Bibliographic Details
Published in:Earth and planetary science letters Vol. 368; pp. 101 - 109
Main Authors: Yamaguchi, A., Mikouchi, T., Ito, M., Shirai, N., Barrat, J.A., Messenger, S., Ebihara, M.
Format: Journal Article
Language:English
Published: Elsevier B.V 15-04-2013
Elsevier
Subjects:
chronology
Earth Sciences
elemental transport
Environmental Sciences
Fracture mechanics
Geochemistry
Global Changes
Melting
Melts
metamorphism
Phases
Plagioclase
planetary basalts
Planetology
Pyroxenes
Sciences of the Universe
Titanium
chronology
metamorphism
geochemistry
elemental transport
planetary basalts
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Summary:Incompatible elements (IEs) such as K, P, Ti, and rare earth elements (REEs) provide important constraints on the geochemistry and chronology of basaltic meteorites, most of which experienced complicated post-crystallization histories. These elements are immobile under subsolidus conditions because of their slow diffusion rates in planetary basalt minerals such as pyroxene and plagioclase. Thus, IEs are considered to preserve in most cases, reliable records of formation processes, even in ancient rocks that have undergone moderate thermal processing. However, observations of natural planetary samples suggest that melting of IE accessory carrier phases enhances the mobilization of such elements. Here we show that IEs are rapidly transported by near-solidus partial melting of highly IE-enriched minor phases including Ca-phosphate and Ti-rich phases. These partial melts occur as interconnected veins along cracks and fractures, and as thin films on surfaces of pore spaces, indicating that the melt mobilization is driven by surface tension. The melt transport provides the necessary condition for melt migration consistent with the presence of the depleted basaltic eucrites. Also, reaction between major minerals pyroxene and plagioclase, and partial melts may cause disturbance and resetting of some isotopic systems. These results have important implications for a range of geochemical investigations. In particular, the elemental fractionation resulting from such partial melting may result in improper age determinations. ► Incompatible elements are mobilized rapidly by near-solidus partial melting. ► Mobilization of early stages of partial melts is driven by surface tension. ► The melt transport provides the necessary condition for melt migration. ► The mechanism provides implications for a range of geochemical investigations.
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ISSN:0012-821X
1385-013X
DOI:10.1016/j.epsl.2013.02.036