Your search keyword '"carbonate fault"' showing total 2 results

1. Crustal-scale fluid circulation and co-seismic shallow comb-veining along the longest normal fault of the central Apennines, Italy

Author

I. Tonguç Uysal, Antonio Caracausi, Jian-xin Zhao, Francesca Castorina, Stefano M. Bernasconi, Luca Smeraglia, Eugenio Carminati, Chiara Boschi, Andrea Luca Rizzo, Carlo Doglioni, Fabrizio Berra, Francesco Italiano, Andrea Billi, Smeraglia, L, Bernasconi, S, Berra, F, Billi, A, Boschi, C, Caracausi, A, Carminati, E, Castorina, F, Doglioni, C, Italiano, F, Rizzo, A, Uysal, I, and Zhao, J

Subjects

010504 meteorology & atmospheric sciences, Outcrop, carbonate fault, fault-fluid interaction, Active fault, Slip (materials science), Induced seismicity, 010502 geochemistry & geophysics, 01 natural sciences, Mantle (geology), comb fracture, fault–fluid interaction, chemistry.chemical_compound, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), calcite vein, Fluid inclusions, Petrology, calcite veins, carbonate faults, comb fractures, fluid inclusions, seismicity, geophysics, geochemistry and petrology, earth and planetary sciences (miscellaneous), space and planetary science, 0105 earth and related environmental sciences, Calcite, fluid inclusion, Geophysics, chemistry, Space and Planetary Science, Meteoric water, Geology

Abstract

The extensional Val Roveto Fault, which is the longest exhumed potentially-seismogenic structure of central Apennines, Italy, is examined to constrain earthquake-related fluid circulation and fluid sources within shallow carbonate-hosted faults. The study focuses on fault-related comb and slip-parallel veins that are calcite-filled and cut through the principal surface of the Val Roveto Fault. We observe multiple crack-and-seal events characterized by several veining episodes, probably related to different slip increments along the fault plane. We show that vein calcite precipitated in Late Pleistocene time below the present-day outcrop level at a maximum depth of similar to 350 m and temperatures between 32 and 64 degrees C from meteoric-derived fluids modified by reactions with crustal rocks and with a mantle contribution (up to similar to 39%). The observed warm temperatures are not compatible with a shallow (

Published

2018

2. Phyllosilicate injection along extensional carbonate-hosted faults and implications for co-seismic slip propagation: Case studies from the central Apennines, Italy

Author

Carlo Doglioni, Andrea Billi, Luca Aldega, Luca Smeraglia, and Eugenio Carminati

Subjects

010504 meteorology & atmospheric sciences, carbonate fault, Slip (materials science), Fault (geology), 010502 geochemistry & geophysics, 01 natural sciences, deformation mechanisms, chemistry.chemical_compound, Marl, Petrology, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Geology, Tectonics, Deformation mechanism, chemistry, earthquake, Carbonate, Siliciclastic, Sedimentary rock, phyllosilicate, clay injection, Seismology

Abstract

We document phyllosilicates occurrence along five shallow (exhumed from depths < 3 km) carbonate-hosted extensional faults from the seismically-active domain of the central Apennines, Italy. The shallow portion of this domain is characterized by a sedimentary succession consisting of ∼5–6 km thick massive carbonate deposits overlain by ∼2 km thick phyllosilicate-rich deposits (marls and siliciclastic sandstones). We show that the phyllosilicates observed within the studied carbonate-hosted faults derived from the overlying phyllosilicate-rich sedimentary deposits and were involved in the faulting processes. We infer that, during fault zone evolution, the phyllosilicates downward injected into pull-aparts (i.e., dilational jogs) that were generated along staircase extensional faults. With further displacement accumulation, the clayey material was smeared and concentrated into localized layers along the carbonate-hosted fault surfaces. These layers are usually thin (a few centimeters to decimeters thick), but can reach also a few meters in thickness. We suggest that, even in tectonic settings dominated by high frictional strength rocks (e.g., carbonates), localized layers enriched in weak phyllosilicates can occur along shallow fault surfaces thus reducing the expected fault strength during earthquakes, possibly promoting co-seismic slip propagation up to the Earth's surface.

Published

2016