Mantle wedge deformation recorded by high-temperature peridotite fabric superposition and hydrous retrogression (Limo massif, Cabo Ortegal, NW Spain)

The Limo harzburgites constitute a hm-thick tectonic stack where extremely elongated meter-scale sheath folds occur, bearing axes parallel to the macroscopic lineation recognized across the whole complex. They can be identified as close to L-type tectonites, with a weak foliation, a well-developed stretching, and a mineral lineation defined by the mineral assemblage in equilibrium. The linear fabric is recognizable at every scale, from aerial photos to the crystallographic orientation of the harzburgite-forming minerals measured by means of the electron back-scatter diffraction technique. These rocks registered initial deformation under high-temperature and low water fugacity conditions at low stress levels in an anhydrous mantle wedge context, as it is inferred from the activity of the 100](010) slip system in olivine. Then, the ongoing eo-Variscan subduction incorporated fluid/melts from the subducting plate into the suprasubduction mantle wedge zone. The variation in the ambient physicochemical conditions led to the operation of the 001](010) slip system in olivine, indicative of lower temperature and higher water fugacity and stress levels. These changes are recorded, too, by synkinematic recrystallization of oriented chlorite. The L-type fabric of clinopyroxene points to constriction conditions during deformation. The active deformational processes continued along the subduction conduit with the thrust of the peridotites onto the high-pressure granulites of the Bacariza Formation. Posteriorly, the whole ensemble would have shared a common deformational history related to exhumation and initial amphibolitization. Subsequent deformation processes under greenschist facies conditions took place until effective continental collision during the Early Carboniferous gave rise to the Variscan orogen.