Abstract
Arc-continent collision, followed by subduction polarity flip, occurs during closure of oceanic basins and contributes to the growth of continental crust. Such a setting may lead to a highly unusual association of ultrapotassic and mid-ocean ridge basalt (MORB)-type volcanic rocks as documented here from an Ordovician succession of the Scandinavian Caledonides. Interbedded with deep-marine turbidites, pillow basalts evolve from depleted-MORB (εNdt 9.4) to enriched-MORB (εNdt 4.8) stratigraphically upward, reflecting increasingly deeper melting of asthenospheric mantle. Intercalated intermediate to felsic lava and pyroclastic units, dated at ca. 474−469 Ma, are extremely enriched in incompatible trace elements (e.g., Th) and have low εNdt (−8.0 to −6.6) and high Sri (0.7089−0.7175). These are interpreted as ultrapotassic magmas derived from lithospheric mantle domains metasomatized by late Paleoproterozoic to Neoproterozoic crust-derived material (isotopic model ages 1.7−1.3 Ga). Detrital zircon spectra reveal a composite source for the interbedded turbidites, including Archean, Paleo-, to Neoproterozoic, and Cambro-Ordovician elements; clasts of Hølonda Porphyrite provide a link to the Hølonda terrane of Laurentian affinity. The entire volcano-sedimentary succession is interpreted to have formed in a rift basin that opened along the Laurentian margin as a result of slab rollback subsequent to arc-continent collision, ophiolite obduction and subduction polarity flip. The association of MORBs and ultrapotassic rocks is apparently a unique feature along the Caledonian-Appalachian orogen. Near-analogous modern settings include northern Taiwan and the Tyrrhenian region of the Mediterranean, but other examples of strictly concurrent MORB and ultrapotassic volcanism remain to be documented.
Highlights
Ophiolites, island arcs and associated sedimentary basins are preserved in many ancient orogens, playing a crucial role in identifying oceanic sutures and reconstructing the opening and closure history of ancient oceanic basins (e.g., Burke et al, 1977)
Detrital zircon spectra reveal a composite source for the interbedded turbidites, including Archean, Paleo, to Neoproterozoic, and Cambro-Ordovician elements; clasts of Hølonda Porphyrite provide a link to the Hølonda terrane of Laurentian affinity
The entire volcano-sedimentary succession is interpreted to have formed in a rift basin that opened along the Laurentian margin as a result of slab rollback subsequent to arccontinent collision, ophiolite obduction and subduction polarity flip
Summary
Ophiolites, island arcs and associated sedimentary basins are preserved in many ancient orogens, playing a crucial role in identifying oceanic sutures and reconstructing the opening and closure history of ancient oceanic basins (e.g., Burke et al, 1977). Overlying the Bolhøgdin unit is a ∼1.6-kmthick succession of variably calcareous and quartz-rich, gray to greenish-gray turbiditic graywackes, ranging from thick-bedded sandstone with conglomerates (graded beds
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