Abstract
The Betic Ophiolites consist of numerous tectonic slices, metric to kilometric in size, of eclogitized mafic and ultramafic rocks associated to oceanic metasediments, deriving from the Betic oceanic domain. The outcrop of these ophiolites is aligned along 250 km in the Mulhacen Complex of the Nevado-Filabride Domain, located at the center-eastern zone of the Betic Cordillera (SE Spain). According to petrological/geochemical inferences and SHRIMP (Sensitive High Resolution Ion Micro-Probe) dating of igneous zircons, the Betic oceanic lithosphere originated along an ultra-slow mid-ocean ridge, after rifting, thinning and breakup of the preexisting continental crust. The Betic oceanic sector, located at the westernmost end of the Tethys Ocean, developed from the Lower to Middle Jurassic (185–170 Ma), just at the beginning of the Pangaea break-up between the Iberia-European and the Africa-Adrian plates. Subsequently, the oceanic spreading migrated northeastward to form the Ligurian and Alpine Tethys oceans, from 165 to 140 Ma. Breakup and oceanization isolated continental remnants, known as the Mesomediterranean Terrane, which were deformed and affected by the Upper Cretaceous-Paleocene Eo-Alpine high-pressure metamorphic event, due to the intra-oceanic subduction of the Jurassic oceanic lithosphere and the related continental margins. This process was followed by the partial exhumation of the subducted oceanic rocks onto their continental margins, forming the Betic and Alpine Ophiolites. Subsequently, along the Upper Oligocene and Miocene, the deformed and metamorphosed Mesomediterranean Terrane was dismembered into different continental blocks collectively known as AlKaPeCa microplate (Alboran, Kabylian, Peloritan and Calabrian). In particular, the Alboran block was displaced toward the SW to occupy its current setting between the Iberian and African plates, due to the Neogene opening of the Algero-Provencal Basin. During this translation, the different domains of the Alboran microplate, forming the Internal Zones of the Betic and Rifean Cordilleras, collided with the External Zones representing the Iberian and African margins and, together with them, underwent the later alpine deformation and metamorphism, characterized by local differences of P-T (Pressure-Temperature) conditions. These Neogene metamorphic processes, known as Meso-Alpine and Neo-Alpine events, developed in the Nevado-Filabride Domain under Ab-Ep amphibolite and greenschists facies conditions, respectively, causing retrogradation and intensive deformation of the Eo-Alpine eclogites.
Highlights
IntroductionThe ultramafic and mafic rocks included in the Mulhacén Complex of the Betic Cordillera (SE Spain; Figure 1) have been interpreted as an eclogitized ophiolite association, i.e., metamorphosed remnants of a Mesozoic oceanic lithosphere since the 1970s (Puga [1], Puga and Díaz de Federico [2])
The ultramafic and mafic rocks included in the Mulhacén Complex of the Betic Cordillera (SE Spain; Figure 1) have been interpreted as an eclogitized ophiolite association, i.e., metamorphosed remnants of a Mesozoic oceanic lithosphere since the 1970s (Puga [1], Puga and Díaz de Federico [2]).This hypothesis relating the Betic Ophiolite Association to a Mesozoic oceanic basin was criticized at the beginning, due to the paucity of outcrops conforming to the three layers model defined for Ophiolites in the Penrose Conference (1972), i.e., sections including peridotites/serpentinites, gabbros/basalts and deep sea sediments, such cherts, hypothetically corresponding to the stratigraphy of the oceanic lithosphere
Of the zircons separated from eclogitized gabbros and dolerites of the Ophiolites, to East we have coloured the bands indicating the location of the following Mesozoic Betic Domains: the Subbetic margin, the Veleta Complex (VC), and the different original domains corresponding to the continental tectonic units forming part of the Mulhacén Complex: Caldera and Sabinas
Summary
The ultramafic and mafic rocks included in the Mulhacén Complex of the Betic Cordillera (SE Spain; Figure 1) have been interpreted as an eclogitized ophiolite association, i.e., metamorphosed remnants of a Mesozoic oceanic lithosphere since the 1970s (Puga [1], Puga and Díaz de Federico [2]). Betic basalts/gabbros do not conform to Normal Mid Oceanic Ridge Basalt (N-MORB) features, i.e., tholeiitic character and extreme depletion in incompatible trace elements, and/or that the Betic ultramafic rocks tend to be less residual (i.e., lherzolite, scarcely depleted by partial melting) with respect to the abyssal peridotites having prevalent harzburgite composition This criticism on the oceanic nature of the BOA has been largely bypassed by recent papers which coupled radiometric dating to new petrological and geochemical studies (such as those in [13,14,15,16,17,18,19,20,21,22,23], among others), certainly ascribing the provenance of some BOA outcrops to a MORB-type tectonic setting, or to an Ocean-Continent-Setting (OCT). Tethys puzzle and the definition of its paleogeographic and geodynamic evolution contributes to the understanding of the current geological configuration of the Central-Western Mediterranean area
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