Abstract
The origin and evolution of subcontinental lithospheric mantle (SCLM) are important issues of Earth’s chemical and physical evolution. Here, we report detailed textural and chemical analyses on a mantle xenolith suite from Befang (Oku Volcanic Group, Cameroon Volcanic Line), which represents a major tectono-magmatic structure of the African plate. The samples are sourced from spinel-facies mantle and are dominated by lherzolites. Their texture is cataclastic to porphyroclastic, and foliation defined by grain-size variation and alignment of spinel occurs in part of peridotites. Spinel is interstitial and has amoeboidal shape. Clinopyroxene REE patterns are similar to those of Depleted MORB Mantle (DMM) except LREEs, which vary from depleted to enriched. The A-type olivine fabric occurs in the subset of one harzburgite and 7 lherzolites studied by EBSD. Orthopyroxene shows deformation consistent with olivine. The fabric of LREE-enriched clinopyroxene is equivalent to those of orthopyroxene and olivine, whereas spinel and LREE-depleted clinopyroxene are oriented independently of host rock fabric. The textural, chemical and thermobarometric constraints indicate that the Befang mantle section was refertilised by MORB-like melt at pressures of 1.0–1.4 GPa and temperatures slightly above 1200–1275 °C. The olivine-orthopyroxene framework and LREE-enriched clinopyroxene preserve the protolith fabric. In contrast, the LREE-depleted clinopyroxene, showing discordant deformation relative to the olivine-orthopyroxene protolith framework, and amoeboidal spinel crystallized from the infiltrating melt. The major element and REEs composition of minerals forming the Befang peridotites indicate subsequent reequilibration at temperatures 930–1000 °C. This was followed by the formation of websterite veins in the lithospheric mantle, which can be linked to Cenozoic volcanism in the Cameroon Volcanic Line that also brought the xenoliths to the surface. This study therefore supports the origin of fertile SCLM via refertilization rather than by extraction of small melt fractions, and further emphasizes the involvement of depleted melts in this process.
Highlights
Subcontinental lithospheric mantle (SCLM) forms the lower, sub-Moho parts of continental plates
We describe the xenolith suite coming from Befang in the Oku Volcanic Group (OVG), part of the Cameroon Volcanic Line in the western part of equatorial Africa (Fig. 1a)
The continental part of the Cameroon Volcanic Line is situated on the Central African Orogenic Belt
Summary
Subcontinental lithospheric mantle (SCLM) forms the lower, sub-Moho parts of continental plates. The study of Gallacher and Bastow (2012) shows that the lithosphere beneath the CVL differs from that typical of hot-spots or rifts in that there is no evidence for extensive melting in the crust, or for addition of mafic intrusions to the lower/middle crust by underplating This suggests that potential temperatures in the mantle are not increased and indicates alternative mechanisms producing small melt fractions, like shear zones or delamination (Gallacher and Bastow 2012). Lee et al (1996) showed that the xenolith minerals are fertile in terms of major elements and that clinopyroxenes from Mt. Cameroon, Mt. Oku and Biu Plateau have REE patterns which are LREE-depleted, REE-enriched or HREE-depleted. Liu et al (2017) presented Re–Os TRD ages varying between 0.12 and 2.05 Ga, but proposed that the age of depletion
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