The origin of Proterozoic massif-type anorthosites: evidence from interactions between crustal xenoliths and basaltic magma

doi:10.1144/gsjgs.156.1.0041

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Journal of the Geological Society; 1999; v. 156; issue.1; p. 41-46;
DOI: 10.1144/gsjgs.156.1.0041
© 1999 Geological Society of London

Article

The origin of Proterozoic massif-type anorthosites: evidence from interactions between crustal xenoliths and basaltic magma

T. J. DEMPSTER, R. J. PRESTON¹ & B. R. BELL

Division of Earth Sciences, Department of Geography, University of Glasgow, Glasgow G12 8QQ, United Kingdom

Plagioclase-rich reaction zones occur around numerous aluminouscrustal xenoliths within a suite of Palaeogene sub-volcanicbasic sheets on the Isle of Mull, NW Scotland. The xenolithsconsist of a glassy core, containing mullite needles, generatedfrom the melting of pelitic source rocks. Thick plagioclasemantles grew at the interface between the aluminous liquid andthe enclosing basaltic magma and provide a high-level analoguefor the petrogenesis of Proterozoic massif-type anorthosites.Similar interactions between mantle-derived basic magmas pondedat the base of the crust and relatively Al-rich lower crustallithologies would result in the precipitation of large volumesof plagioclase. Anorthosite massifs were then emplaced at highercrustal levels as crystal-rich mushes within relatively juvenileProterozoic crust. The model negates the need to crystallizelarge volumes of mafic minerals prior to the production of plagioclase-saturatedliquids, and also accounts for the significant influence ofcrustal sources on the isotopic signatures of all members ofthe anorthosite suite.

Key Words: Proterozoic • anorthosite • geochemistry • plagioclase • xenoliths

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