Geochronology, geochemistry and Sr-Nd, Hf-O isotope systematics of the Linte massif, Adamawa - Yade domain, Cameroon: Implications on the evolution of the Central African Fold Belt

• Published in: Precambrian research Vol. 375; p. 106675
• Main Authors: Yomeun, Bovari Syprien, Wang, Wei, Kamani, Michele Sandra Kamguia, Tchouankoue, Jean Pierre, Jiang, Ying-De, Huang, Si-Fang, Ndonfack, Kevin Igor Azeuda, Xue, Er-Kun, Lu, Gui-Mei, Basua, Emmanuel Archelaus Afanga
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.07.2022
• Subjects: Central African Fold Belt; Linte syenitic massif; Neoproterozoic plutonism; Pan-African orogeny; Shoshonitic; Subduction-collision setting; Neoproterozoic plutonism; Central African Fold Belt; Pan-African orogeny; Linte syenitic massif; Subduction-collision setting; Shoshonitic
• ISSN: 0301-9268; 1872-7433
• DOI: 10.1016/j.precamres.2022.106675

•The Linte massif reveals a protracted magmatism which lasted at least 60 Ma.•Rocks show geochemical affinities of I-type, shoshonitic and metaluminous granitoids.•The 660 and 630 Ma rocks originate from source involving mantle material which could have been mingled or mixed with crustal component while the 600 Ma rocks come from crustal material.•They were formed during the syn- collisional phase of the Pan-African orogeny. The Central African Fold Belt (CAFB) holds a key position in understanding the process and implications of the Pan-African orogeny in central Africa. However, it has not been fully understood as geological information on some vital domains is not yet available. The Linte massif in the Adamawa-Yade, one of the unrepresented terranes, was investigated and its whole rock geochemical, zircon U-Pb geochronology and Hf-O isotope characteristics and whole rock Sr-Nd data are presented and discussed here. The Linte massif is largely constituted of syenite and subordinate monzonite. The zircon U - Pb dating reveals three major ages at 660, 630 and 600 Ma, indicating a protracted magmatism which lasted at least 60 Ma, during the Neoproterozoic. The rocks are shoshonites, I-type and metaluminous. They have high LILEs (Cs, Rb, Ba and Sr), HFSEs (Th and U) and LREE contents. Their Nb/U, Ta/U, Ce/Pb, Th/La and Th/U ratios, δ18Ozrn (5.3–7.6‰) and zircon εHf(t) (−14.7 to +3.2), point toward predominantly crustal with or without a mantle component in the sources. The negative εNd(t) values (−8.1 to −10.0), Paleoproterozoic Nd-TDM model ages (ca. 1700–1900 Ma), Hf-TDM2 ages of ca. 1300–2400 Ma of zircon grains in Neoproterozoic rocks underline their derivation from Mesoproterozoic to Paleoproterozoic basement rocks. The lithospheric mantle-generated heat facilitated partial melting in the sources region, as inferred from the shoshonitic affinity and the subduction-related geochemical features (Nb, Ta and Ti depletion). A mainly crustal source with a minor mantle component is inferred for the 660 Ma magmatism and for the 630 Ma rocks emplaced during crustal thickening. On the other hand, the 600 Ma (youngest) magmatic rocks were derived from a crustal source. We infer a subduction-collision setting for the Linte massif during the 660–600 Ma interval. The 630–600 Ma interval of the culmination of collision is consistent with the timing of the main convergence of the Brasiliano Orogeny recorded in South America (∼630–600 Ma), suggesting continuation of tectonic features into the western Gondwana.