Your search keyword '"Tectonic"' showing total 8 results

1. Neogene and Pleistocene geodynamics: the paleoseismic evolution of Armorica (Western France).

Author

Vliet-Lanoe, Brigitte Van, Authemayou, Christine, Roy, Pascal Le, Renouf, John C., Combes, Philippe, Ego, Frederic, Parrino, Nicolo, and Gambino, Salvatore

Subjects

NEOGENE Period, GLACIAL isostasy, GEODYNAMICS, PLEISTOCENE Epoch, SURFACE fault ruptures, SHEAR strain

Abstract

The evolution of the passive Armorican margin (Western France) during the Neogene and Quaternary was analyzed using field data. The morphology of the margin attests to a late Hercynian shaping, further deformation during the Mesozoic mid-Atlantic opening, during the Alpine Orogeny, and ultimately, a Late Cenozoic uplift, mostly related to an onshore isostatic accommodation in response to erosion and limited tectonic activity. A very limited strike-slip dynamic, with very low seismicity, accommodated the Neogene-Pleistocene N170 strains around the rigid Armorican terrane. The South Armorican domain and English Channel floor include shear zones that adjusted the Alpine convergence, facilitating its transpressive slip to the west. The Permo-Triassic N150 faults were reactivated during the inversion phases that began after the Bartonian under the distal control of the Alpine convergence and the decrease in the Atlantic spreading rate after 34 Ma. The Armorican marine platforms were stable after the late Eocene and slightly subsident, experiencing pulsed episodes of transient lithospheric doming during the Neogene and Quaternary. Co-seismic activity onshore without surface rupture was recorded around ~5.3 Ma, ~3.7 Ma, ~2.4-1.2 Ma, and ~400-250 ka, in tandem with an inland exhumation driven by isostatic adjustment due to an intensification of periglacial erosion at the onset of the early interstadials or by agriculture. Low-magnitude and ubiquitous shallow seismic activities seem to be related today to an isostatic uplifted old brittle-ductile transition due to the accumulation of shearing strain. [ABSTRACT FROM AUTHOR]

Published

2024

2. Neogene and Pleistocene geodynamics: the paleoseismic evolution of Armorica (Western France)

Author

Brigitte Van Vliet-Lanoë, Christine Authemayou, Pascal Le Roy, John C. Renouf, Philippe Combes, and Frederic Ego

Subjects

paleoseismicity, sea level, climate, uplift, erosion, tectonic, Science

Abstract

The evolution of the passive Armorican margin (Western France) during the Neogene and Quaternary was analyzed using field data. The morphology of the margin attests to a late Hercynian shaping, further deformation during the Mesozoic mid-Atlantic opening, during the Alpine Orogeny, and ultimately, a Late Cenozoic uplift, mostly related to an onshore isostatic accommodation in response to erosion and limited tectonic activity. A very limited strike–slip dynamic, with very low seismicity, accommodated the Neogene–Pleistocene N170 strains around the rigid Armorican terrane. The South Armorican domain and English Channel floor include shear zones that adjusted the Alpine convergence, facilitating its transpressive slip to the west. The Permo-Triassic N150 faults were reactivated during the inversion phases that began after the Bartonian under the distal control of the Alpine convergence and the decrease in the Atlantic spreading rate after 34 Ma. The Armorican marine platforms were stable after the late Eocene and slightly subsident, experiencing pulsed episodes of transient lithospheric doming during the Neogene and Quaternary. Co-seismic activity onshore without surface rupture was recorded around ∼5.3 Ma, ∼3.7 Ma, ∼2.4–1.2 Ma, and ∼400–250 ka, in tandem with an inland exhumation driven by isostatic adjustment due to an intensification of periglacial erosion at the onset of the early interstadials or by agriculture. Low-magnitude and ubiquitous shallow seismic activities seem to be related today to an isostatic uplifted old brittle–ductile transition due to the accumulation of shearing strain.

Published

2024

3. Editorial: Earthquake swarms and complex seismic sequences in tectonic and volcanic areas

Author

Maria Mesimeri, Luigi Passarelli, Simone Cesca, Francesco Maccaferri, and Federica Lanza

Subjects

earthquake swarm, seismicity analysis, volcano, seismic sequence, tectonic, Science

Published

2023

4. Editorial: Permian-Triassic Tethyan orogeny along the southern Eurasian margin

Author

Mingcai Hou, Fuhao Xiong, Changqian Ma, Gillian R. Foulger, and Shengyao Yu

Subjects

Tethyan, magmatism, metamorphism, sediment provenance, tectonic, geodynamic, Science

Published

2023

5. Active degassing of crustal CO2 in areas of tectonic collision: A case study from the Pollino and Calabria sectors (Southern Italy)

Author

Paolo Randazzo, Antonio Caracausi, Alessandro Aiuppa, Carlo Cardellini, Giovanni Chiodini, Carmine Apollaro, Michele Paternoster, Angelo Rosiello, and Giovanni Vespasiano

Subjects

helium, carbon dioxide, tectonic, Earth degassing, metamorphism, Science

Abstract

Carbon dioxide (CO2) is released from the Earth’s interior into the atmosphere through both volcanic and non-volcanic sources in a variety of tectonic settings. A quantitative understanding of CO2 outgassing fluxes in different geological settings is thus critical for decoding the link between the global carbon budget and different natural processes (e.g., volcanic eruption and earthquake nucleation) and the effects on the climate evolution over geological time. It has recently been proposed that CO2 degassing from non-volcanic areas is a major component of the natural CO2 emission budget, but available data are still sparse and incomplete. Here, we report the results of a geochemical survey aimed at quantifying CO2 emissions through cold and thermal springs of the tectonically active Pollino Massif and Calabrian arc (Southern Italy). The chemical ad isotopic (He and C) composition of fifty-five dissolved gas samples allows to identify two different domains: 1) a shallow system dominated by gas components of atmospheric signature (helium, hereafter He) and biogenic origin (C), and 2) a deeper system in which crustal/deep fluids (CO2 and He) are dominant. The measured He isotope ratios range from 0.03 to 1.1 Ra (where Ra is the He isotopic ratio in the atmosphere) revealing a variable atmospheric contamination. Furthermore, the He isotopic data indicate the presence of traces of mantle He contributions (2%–3%) in the thermal groundwater. The prevailing low R/Ra values reflect the addition of crustal radiogenic 4He during groundwater circulation. Using helium and carbon isotope data, we explore the possible sources of fluids and the secondary processes (dissolution/precipitation) that act to modify the chemistry of pristine volatiles. For the thermal springs, we estimate a deep C output of 2.3 x 107 to 6.1 x 108 mol year−1. These values correspond to deep CO2 fluxes per square km comparable with those estimated in several active and inactive volcanic areas and in continental regions affected by metamorphic CO2 degassing (e.g., the southern margin of the Tibetan Plateau).

Published

2022

6. The Early Miocene Provenance Shift of ODP Site 1177 and Implications for the Tectonic Evolution of the Shikoku Basin, Philippine Sea Plate

Author

Wei Liu, Wanyi Feng, Congcong Gai, Yang Zhou, Yi Zhong, Wei Cao, Yuanjie Li, Xixi Zhao, and Qingsong Liu

Subjects

ODP site 1177, provenance shift, philippine sea plate, tectonic, rock-magnetism, Science

Abstract

The Ocean Drilling Program Site 1177 recovered the oldest (∼23 Ma) sedimentary records in the Shikoku Basin, northeastern part of the Philippine Sea Plate. Changes in sediment provenances bear important implications for the tectonic evolution of the Philippine Sea Plate, but existing data are still controversial for the early Miocene. By integrating Sr-Nd isotopes, rock-magnetic parameters, diffuse reflectance spectroscopy, and the previous data on the detrital zircons and clay minerals from Site 1177, we found that a significant provenance shift occurred at ∼16.5 Ma. The sediments of Site 1177 before ∼16.5 Ma were mainly sourced from the Pearl River and Izu-Bonin Arc, but changed to the Yangtze River and Izu-Bonin Arc sources after that. This provenance shift was strongly linked with the northward motion and clockwise rotation of the Shikoku Basin in the Miocene, which marked the final time of separation between the Shikoku Basin and the South China Sea.

Published

2022

7. Editorial: Seismicity in Volcanic Areas

Author

Derek Keir, Luca De Siena, Cécile Doubre, Jessica H. Johnson, Francesco Maccaferri, and Luigi Passarelli

Subjects

earthquake, volcano, tectonic, magma “mush”, dyke, eruption, Science

Published

2021

8. The 2011–2014 Pollino Seismic Swarm: Complex Fault Systems Imaged by 1D Refined Location and Shear Wave Splitting Analysis at the Apennines–Calabrian Arc Boundary

Author

Marina Pastori, Lucia Margheriti, Pasquale De Gori, Aladino Govoni, Francesco Pio Lucente, Milena Moretti, Alessandro Marchetti, Rita Di Giovambattista, Mario Anselmi, Paolo De Luca, Anna Nardi, Nicola Piana Agostinetti, Diana Latorre, Davide Piccinini, Luigi Passarelli, Claudio Chiarabba, Pastori, M, Margheriti, L, De Gori, P, Govoni, A, Lucente, F, Moretti, M, Marchetti, A, Di Giovambattista, R, Anselmi, M, De Luca, P, Nardi, A, Piana Agostinetti, N, Latorre, D, Piccinini, D, Passarelli, L, Chiarabba, C, and Water and Climate Risk

Subjects

1D and DD localizations, 010504 meteorology & atmospheric sciences, Inversion (geology), 1D and DD localization, Induced seismicity, Fault (geology), 010502 geochemistry & geophysics, shear wave splitting, 01 natural sciences, seismic swarm, tectonics, Anisotropy, lcsh:Science, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Shear wave splitting, SDG 11 - Sustainable Cities and Communities, Tectonics, tectonic, Seismic hazard, geodynamics and seismicity, Slab, General Earth and Planetary Sciences, lcsh:Q, Seismology, Geology

Abstract

In the years between 2011 and 2014, at the edge between the Apennines collapsing chain and the subducting Calabrian arc, intense seismic swarms occurred in the Pollino mountain belt. In this key region, ML 5.0 shock occurred in October 2012. This latter comes after a ML four nucleated in May 2012 and followed by aseismic slip episodes. In this study, we present accurate relocations for ∼6,000 earthquakes and shear-wave splitting analysis for ∼22,600 event-station pairs. The seismicity distribution delineates two main clusters around the major shocks: in the north-western area, where the ML 5.0 occurred, the hypocenters are localized in a ball-shaped volume of seismicity without defining any planar distribution, whilst in the eastern area, where the ML 4.3 nucleates, the hypocenters define several faults of a complex system of thrusts and back-thrusts. This different behavior is also imaged by the anisotropic parameters results: a strong variability of fast directions is observed in the western sector, while stable orientations are visible in the eastern cluster. This tectonic system possibly formed as a positive flower structure but as of today, it accommodates stress on normal faults. The deep structure imaged by refined locations is overall consistent with the complex fault system recently mapped at the surface and with patterns of crustal anisotropy depicting fractures alignment at depth. The possible reactivation of inherited structures supports the important role of the Pollino fault as a composite wrench fault system along which, in the lower Pleistocene, the southward retreat of the ionian slab was accommodated; in this contest, the inversion of the faults kinematics indicates a probable southward shift of the slab edge. This interpretation may help to comprehend the physical mechanisms behind the seismic swarms of the region and defining the seismic hazard of the Pollino range: nowadays a region of high seismic hazard although no strong earthquakes are present in the historical record.

Published

2021