Abstract
AbstractPlagioclase‐rich granulites exposed on the Lofoten archipelago, Northern Norway, display strain localization in pseudotachylytes as well as ductile shear zones that formed under similar high‐pressure and high‐temperature conditions. Pseudotachylytes or pseudotachylyte networks reveal no or very little hydration, whereas ductile shear zones reveal significant hydration. We combine these observations from the field with experimental results to characterize the structural evolution of brittle faults in plagioclase‐rich rocks at conditions of the lower continental crust. We performed a series of deformation experiments on intact granulite samples prepared from a natural granulite sample at 2.5 GPa confining pressure, a strain rate of 5 × 10−5 s−1, and temperatures of 700°C and 900°C to total strains of ~7–8% and ~33–36%. Samples were either deformed “as‐is” or with ~1 wt.% H2O added. Striking similarities between the experimental and natural microstructures suggest that the transformation of precursory brittle structures into ductile shear zones at eclogite‐facies conditions is most effective in samples deformed with added water triggering reaction and subsequent plastic deformation of the products along the faults and in the adjacent wall‐rock.
Highlights
The rheology of rocks and especially the localization of strain in the lower continental crust is of great importance since the flow behavior of the lower continental crust strongly influences the deformation behavior of the entire continental lithosphere
Plagioclase‐rich granulites exposed on the Lofoten archipelago, Northern Norway, display strain localization in pseudotachylytes as well as ductile shear zones that formed under similar high‐pressure and high‐temperature conditions
Striking similarities between the experimental and natural microstructures suggest that the transformation of precursory brittle structures into ductile shear zones at eclogite‐facies conditions is most effective in samples deformed with added water triggering reaction and subsequent plastic deformation of the products along the faults and in the adjacent wall‐rock
Summary
The rheology of rocks and especially the localization of strain in the lower continental crust is of great importance since the flow behavior of the lower continental crust strongly influences the deformation behavior of the entire continental lithosphere. Pseudotachylytes and associated deformation features in the adjacent wall rock highlight extreme transient stresses and strain rates that are believed to occur during dynamic rupture propagation (Austrheim et al, 2017; Hawemann, Mancktelow, Wex, et al, 2019, Hawemann, Mancktelow, Pennacchioni, et al, 2019, 2018; Jamtveit et al, 2019; Petley‐Ragan et al, 2019, 2018). Because of the close spatial occurrence of brittle faults and ductile shear zones at a variety of locations worldwide, it has been suggested that ductile shear zones can nucleate on preexisting brittle faults (Guermani & Pennacchioni, 1998; Mancktelow & Pennacchioni, 2005; Menegon et al, 2017; Pennacchioni & Mancktelow, 2007; Pittarello et al, 2012; Segall & Simpson, 1986; Tullis et al, 1990)
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