The origin and evolution of DMM-like lithospheric mantle beneath continents : mantle xenoliths from the Oku Volcanic Group in the Cameroon Volcanic Line, West Africa

2023

Article référencé dans le Web of Science WOS:001036025600001

Puziewicz J., Aulbach S., Kaczmarek M. A., Ntaflos T., Gerdes A., Mazurek Hubert, Kukula A., Matusiak-Malek M., Tedonkenfack S. S. T., Ziobro-Mikrut M.

Journal of Petrology, 2023, 64 (7), p. egad049 [25 p.] ISSN 0022-3530

The lithospheric mantle as sampled by peridotite xenoliths in some continental settings resembles the source of mid-ocean ridge basalts (MORB). Whether this resemblance is a primary feature or the result of post-formation secondary processes remains controversial. Here, the age, origin and thermochemical evolution of fertile continental mantle are constrained based on the chemical composition of minerals in spinel-facies lherzolite and websterite xenoliths from the Wum maar and Befang cinder cone of the Oku Volcanic Group (Cameroon Volcanic Line, West Africa), combined with in-situ Sr isotope compositions of clinopyroxene and fabric investigation by Electron Backscatter Diffraction (EBSD). The majority of lherzolites (here assigned to Group I) consist of minerals with fertile composition (olivine Fo89, Al-rich pyroxenes, spinel Cr 0.08-0.10). Clinopyroxene is LREE-depleted and has depleted Sr-87/Sr-86 (0.7017-0.7020). Crystal-preferred orientation determined by EBSD reveals that clinopyroxene, and sporadically both clino- and orthopyroxene, post-date the olivine framework. Subordinate Group II lherzolites also contain secondary clinopyroxene which is LREE-enriched and has higher Sr-87/Sr-86 (0.7033). In contrast, the scarce lherzolites of Group III are more refractory: they contain 72-78 vol.% olivine, Al-poor pyroxenes, and spinel with Cr 0.18. Clinopyroxene (Sr-87/Sr-86 0.7021) is texturally coeval with olivine and orthopyroxene. Few lherzolites contain amphibole (Sr-87/Sr-86 0.7031) which post-dates the nominally anhydrous minerals. Most of the websterites (Group A) are aluminous (spinel Cr 0.04-0.06) with LREE-depleted clinopyroxene having depleted Sr-87/Sr-86 ratios (0.7017-0.7020) similar to Group I lherzolites. Chemical characteristics of minerals coupled with the crystal-preferred orientation data suggests that Group I lherzolites originated in the spinel stability field by reactive intergranular percolation of an incompatible element-depleted MORB-like melt. Group A websterites likely formed as cumulates from that melt. The Group II lherzolites supposedly occur close to lithosphere-asthenosphere boundary and record interaction with lavas of the Cameroon Volcanic Line, whereas Group III lherzolites occur in the shallow part of the mantle profile and represent the protolith from which the Group I lherzolites were formed. Local crystallization of amphibole and concomitant recrystallization of the host lherzolite were driven by supply of water in an event post-dating the formation of LREE-depleted rejuvenated rocks. Migration of alkaline melts of the CVL apparently did not significantly affect the mineral and chemical composition of the lithospheric mantle, which allowed Group I lherzolites and Group A websterites to retain very low Rb-87/Sr-86 (average 0.002) and depleted Sr-87/Sr-86 ratios in clinopyroxene. This not only indicates their formation in the Paleoproterozoic (similar to 2.0-2.25 Ga), possibly during the Eburnean orogeny at the margin of the Congo craton, but also indicates surprisingly little influence of the regionally recognized Pan-African event.