Abstract

Detailed geological field mapping, integrated with meso- and microstructural investigations, kinematic of the flow and finite strain analyses, combined with geochronology, are fundamental tools to obtain information on the temperature–deformation–timing path of crystalline rocks and shear zone. The Posada-Asinara shear zone (PASZ) in northern Sardinia (Italy) is a steeply dipping km-thick transpressive shear zone. In the study area, located in the Baronie region (NE Sardinia), the presence of mylonites within the PASZ, affecting high- and medium-grade metamorphic rocks, provides an opportunity to quantify finite strain and kinematic vorticity. The main structures of the study area are controlled by a D2 deformation phase, linked to the PASZ activity, in which the strain is partitioned into folds and shear zone domains. Applying two independent vorticity methods, we detected an important variation in the percentage of pure shear and simple shear along the deformation gradient, that increases from south to north. We constrained, for the first time in this sector, the timing of the transpressive deformation by U–(Th)–Pb analysis on monazite. Results indicate that the shear zone has been active at ~325–300 Ma in a transpressive setting, in agreement with the ages of the other dextral transpressive shear zones in the southern Variscan belt.

Highlights

  • Shear zones are characterized by strain localization at different scales and the complex behavior of the involved rocks [1,2,3,4]

  • We present a new dataset of field measurements, meso- and microstructural data, kinematics of the flow, finite strain data combined, and for the first time in this sector of the Posada-Asinara shear zone (PASZ), in situ U–Th–Pb geochronology

  • The principal structures of the D2 phase are controlled by a deformation in which the strain is partitioned into folds and shear zone domains

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Summary

Introduction

Shear zones are characterized by strain localization at different scales and the complex behavior of the involved rocks [1,2,3,4]. The activity of shear zones controls the exhumation of crystalline complexes during the collisional and post-collisional stages of orogenic belts [5,6,7,8,9]. Their geometry and kinematics strongly affect the way by which large crustal blocks are exhumed [7,10,11]. Several vorticity gauges have been developed and used to quantitatively assess kinematic vorticity in natural shear zones [19]

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