Your search keyword '"Catalina Hernandez-Moreno"' showing total 3 results

1. Understanding Paleomagnetic Rotations in Sicily: Thrust Versus Strike-Slip Tectonics

Author

Catalina Hernandez-Moreno, Fabio Speranza, Attilio Sulli, Giuseppe Avellone, Maurizio Gasparo Morticelli, Enrico Di Stefano, Mauro Agate, Speranza, Fabio, Hernandez-Moreno, Catalina, Avellone, Giuseppe, Gasparo Morticelli, Maurizio, Agate, Mauro, Sulli, Attilio, and Di Stefano, Enrico

Subjects

Paleomagnetism, 010504 meteorology & atmospheric sciences, Settore GEO/03 - Geologia Strutturale, paleomagnetism, Thrust, 010502 geochemistry & geophysics, Strike-slip tectonics, rotation, 01 natural sciences, thrust tectonic, Thrust tectonics, Geophysics, strike-slip tectonic, Geochemistry and Petrology, Sicily, Geophysic, Seismology, Geology, 0105 earth and related environmental sciences

Abstract

The paleomagnetic investigation of the western Sicily Maghrebian belt has revealed since the 1970s that large clockwise rotations up to 140° with respect to the Hyblean-African foreland occurred synchronous with Tertiary shortening of the chain. The observation that rotations decrease stepwise from internal to external tectono-stratigraphic units led in the 1990s to a widely accepted model postulating that rotational thrust-sheet emplaced during forward orogenic propagation. More recently, other authors suggested that clockwise rotations from Sicily are conversely the result of late orogenic dextral strike-slip tectonics. Here we report on a paleomagnetic investigation of 30 Jurassic-Eocene sedimentary sites sampled mainly across the WNW-ESE Mt. Kumeta and Rocca Busambra ridges (Trapanese Unit), both bounded to the north by high-angle reverse faults with dextral strike-slip components. We find rotations of 110°–120° at faults of northern ridge margins, which decrease to 80°–90° at ~200m to the south and rise again moving further south. Thus, an excess rotation of 20°–40° due to dextral-strike-slip shear is annulled to the regional rotational background of the Trapanese Unit at only 200m from fault traces, translating to paleomagnetically calculated strike-slip offsets not exceeding 600m. Further north, seven sites sampled in the Imerese Unit, tectonically stacked above the Trapanese Unit, yield a ~130° rotation. Thus, our data confirm that CW rotations in Sicily are predominantly related to thrust-sheet emplacement. Strike-slip tectonics has very limited relevance and gives local rotations that fade out at only 200m from fault planes.

Published

2018

2. Paleomagnetic rotation pattern of the southern Chile fore‐arc sliver (38°S–42°S): A new tool to evaluate plate locking along subduction zones

Author

Catalina Hernandez-Moreno, Anita Di Chiara, and Fabio Speranza

Subjects

geography, Paleomagnetism, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Subduction, Fault (geology), 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, Sinistral and dextral, Shear (geology), Volcano, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Clockwise, Seismology, Geology, 0105 earth and related environmental sciences

Abstract

The Chile fore arc at 37°S–47°S represents the coseismic deformation zone of the 1960 Mw 9.5 Valdivia earthquake. Here we report on the paleomagnetism of 43 Oligocene-Pleistocene volcanic sites from the fore-arc sliver between 38°S and 42°S. Sites were gathered west of the 1000 km long Liquine-Ofqui dextral fault zone (LOFZ) that represents the eastern fore-arc sliver boundary. Nineteen reliable sites reveal that the fore arc is characterized by counterclockwise (CCW) rotations of variable magnitude, except at 40°S–41°S, where ultrafast (>50°/Myr) clockwise (CW) rotations occur within a 30 km wide zone adjacent to the LOFZ. CCW rotation variability (even at close sites) and rapidity (>10°/Myr) suggest that the observed block rotation pattern is related to NW-SE seismically active sinistral faults crosscutting the whole fore arc. According to previously published data, CW rotations up to 170° also occur east of the LOFZ and have been related to ongoing LOFZ shear. We suggest that the occurrence and width of the eastern fore-arc sliver undergoing CW rotations is a function of plate coupling along the subduction zone interface. Zones of high coupling enhance stress normal to the LOFZ, induce high LOFZ strength, and yield a wide deformation zone characterized by CW rotations. Conversely, low coupling imply a weak LOFZ, a lack of CW rotations, and a fore arc entirely dominated by CCW rotations related to sinistral fault kinematics. Our locking inferences are in good agreement with those recently derived by GPS analysis and indicate that seismotectonic segment coupling has remained virtually unchanged during the last 5 Ma.

Published

2016

3. Understanding kinematics of intra-arc transcurrent deformation: Paleomagnetic evidence from the Liquiñe-Ofqui fault zone (Chile, 38-41°S)

Author

Catalina Hernandez-Moreno, Anita Di Chiara, and Fabio Speranza

Subjects

Paleomagnetism, geography, geography.geographical_feature_category, Crust, Fault (geology), Strike-slip tectonics, Strain partitioning, Geophysics, Sinistral and dextral, Geochemistry and Petrology, Clockwise, Shear zone, Seismology, Geology

Abstract

The Liquine-Ofqui fault zone (LOFZ) is a major ~1000 km long dextral shear zone of southern Chile, likely related to strain partitioning of Nazca Plate oblique convergence with South America. To understand block rotation pattern along the LOFZ, we paleomagnetically sampled 55 sites (553 samples) between 38°S and 41°S. We gathered Oligocene to Pleistocene volcanics and Miocene granites at a maximum distance of 20 km from the LOFZ, and at both sides of it. Rotations with respect to South America, evaluated for 36 successful sites, show that crust around the LOFZ is fragmented in small blocks, ~1 to 10 km in size. While some blocks (at both fault edges) undergo very large 150°–170° rotations, others do not rotate, even adjacent to fault walls. We infer that rotations affected equidimensional blocks, while elongated crust slivers were translated subparallel to the LOFZ, without rotating. Rotation pattern across the LOFZ is markedly asymmetric. East of the fault and adjacent to it, rotations are up to 150°–170° clockwise, and fade out ~10 km east of fault. These data support a quasi-continuous crust kinematics, characterized by small rigid blocks drag by the underlying ductile crust flow, and imply 120 km of total fault offset. Conversely, crust west of the LOFZ is cut by seismically active NW-SE sinistral antithetic faults, and yields counterclockwise rotations up to 170° at 8–10 km from LOFZ, besides the unrotated blocks. Further data from the Chile fore arc are needed to understand block rotation kinematics and plate dynamics west of the LOFZ.

Published

2014