Palaeoseismology of the Vilariça Segment of the Manteigas-Bragança Fault in northeastern Portugal

Rockwell, T. K.; Fonseca, João F. B. D.; Madden, C.; Dawson, T. E.; Owen, Lewis A.; Vilanova, Susana; Figueiredo, Paula

doi:10.1144/sp316.15

Cited by 38 publications

(34 citation statements)

References 23 publications

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“…For the slip rate values associated with the initiation of the pull-apart basins we use ~ 16 Ma years (pull-apart basin initiation; Villamor et al, 2004). Those values are 0.05 to 0.1 mm/ yr (Table 1), which are also in agreement with slip rate values of 0.3-0.5 mm/yr in similar NE trending strikeslip faults in the Iberian Massif from paleoseismic studies (Rockwell et al, 2009). For slip rates associated with the S-Raña surface, we use a range of ages from 5 to 2 Ma for the Raña sediments (based on different authors, see discussion in Villamor, 2002 and section 4).…”

Section: Earthquake Magnitudes Associated With the Apfsupporting

confidence: 55%

“…In this latter area, the drainage pattern has also been described as controlled by NE-SW faults (Martín-González, 2009). More recent paleoseismic studies have revealed the Quaternary activity of the Vilariça fault (NE trending fault; fault 23 on Fig 1), with at least two Mw>7 events in the last 14.5 ka with a slip rate of 0.3-0.5mm/yr (Rockwell et al, 2009).…”

Section: Geological Settingmentioning

confidence: 99%

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Contribution of active faults in the intraplate area of Iberia to seismic hazard: The Alentejo-Plasencia Fault

Villamor

Capote

Stirling

et al. 2012

Journal of Iberian Geology

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We present the earthquake potential characterisation of the Alentejo-Plasencia Fault (APF) in the intraplate area of the Iberian Peninsula. The APF displays clear deformation of geomorphic surfaces and sediments of Neogene and younger age and, thus, we consider it to be active within the current tectonic regime. APF fault slip rate values range from 0.01 to 0.1 mm/yr with a preferred value of 0.05 mm/yr. Mw associated to fault rupture ranges from 6.6 to 8.7 using different segmentation models (segments ranging from 20 to 500 km) and various fault scaling relationships. Recurrence intervals derived from slip rate and Mw range from 10 ka to 4 Ma, with preferred values between 20 and 30 ka. Other faults in the interior of Iberia present similar values. Hazard curves produced using all fault sources from the intraplate Iberia show that active faults of the intraplate Iberia do not contribute significantly to seismic hazard at short return periods typical of the building codes (~ 500 year return periods). However, they can be important contributors to hazard at critical facilities (high hazard dams, nuclear power plants, emergency response buildings) where return periods of interest may be 10,000 years or more. Our fault source characterisation is very preliminary (with large uncertainties) and further detailed studies of active faults across the whole plate boundary are required to confirm the values for the intraplate faults presented here.Keywords: Alentejo-Plasencia Fault, active fault, intraplate Iberia, hazard assessment, Spain ResumenEn este trabajo se presenta la caracterización del potencial sísmico de la falla Alentejo-Plasencia (APF) situada en la región intraplaca de la Península Ibérica. La APF muestra una clara deformación de superficies geomorfológicas y sedimentos de edad neógena ISSN (print): 1698-6180. ISSN (online): 1886-7995

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Section: Earthquake Magnitudes Associated With the Apfsupporting

confidence: 55%

Section: Geological Settingmentioning

confidence: 99%

Contribution of active faults in the intraplate area of Iberia to seismic hazard: The Alentejo-Plasencia Fault

Villamor

Capote

Stirling

et al. 2012

Journal of Iberian Geology

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“…The main seismic sequences (Lugo and Orense sequences) are related to faults belonging to the Orense corridor. These corridors penetrate in Portugal and have the same orientation as the Bragança-Vilariça fault corridor, which has a slip rate of 0.2-0.5 mm/a (Cabral, 1989 andRockwell et al, 2009;Cabral et al, 2010), the Verin-Vila Real fault corridor, and some segments of the AlentejoPlasencia fault (Villamor, 2002) (Figs. 11 and 2).…”

Section: Potentially Active Faultsmentioning

confidence: 99%

“…The National Seismic Catalogue, managed by the Instituto Geográfico Nacional (IGN), contains 4,380 historic and instrumental 1989; Cabral and Ribeiro, 1993;Rockwell et al, 2009;Cabral et al, 2010) (Fig. 1) and, although there is plenty of petrologic and structural information about the zone (e.g.…”

Section: Seismicitymentioning

confidence: 99%

Seismicity and potencially active faults in the Northwest and Central-West Iberian Peninsula

Martín-González

Antón

Arévalo

et al. 2012

Journal of Iberian Geology

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The Northwest and Central-West Iberian Peninsula configure an intraplate area far from the active plate boundaries, where the Variscan basement crops out extensively (Iberian Massif). This area of the Iberian Peninsula has been traditionally considered a seismically stable region; however, it presents a moderate intraplate seismicity which indicates the presence of active structures and the occurrence of potentially damaging earthquakes. The scarcity of Mesozoic and Cenozoic deposits makes very difficult to track the record of the more recent tectonic activity and the characterization of active tectonic structures within the Iberian Massif. Nevertheless the seismic sequences of 1995-1997 in Lugo (5.1 mb; IV) and 2003 in Zamora (4.2 Mw) provided important information about the orientation of the present stress tensor, and the distribution of the hypocenters informed about the rupture geometry of the fault planes. The present work integrates geological, geomorphological, structural, and seismological data in order to define the main potentially active faults in the region. Faults trending NE-SW to N-S are potentially active as strike-slip, in some cases with a reverse component, under a NW-SE to N-S compression.

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“…This would be an example of a physical process external to the seismic cycle affecting the faulting process. There are not currently many paleoseismic indicators that sufficiently span the time since the LGM in a way that would allow these predictions to be rigorously tested, though a few studies do offer some observations of long-term fault behavior [e.g., Rockwell et al, 2009]. We therefore present a model-based analysis of the stress changes ocean loading is likely to create and the impact such perturbations would have on observable paleoseismic indicators, so as to better understand the influence sea level rise may have on long-term plate boundary behavior.…”

Section: Introductionmentioning

confidence: 99%

Ocean loading effects on stress at near shore plate boundary fault systems

Luttrell

Sandwell

2010

J. Geophys. Res.

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[1] Changes in eustatic sea level since the Last Glacial Maximum create a differential load across coastlines globally. The resulting plate bending in response to this load alters the state of stress within the lithosphere within a half flexural wavelength of the coast. We calculate the perturbation to the total stress tensor due to ocean loading in coastal regions. Our stress calculation is fully 3-D and makes use of a semianalytic model to efficiently calculate stresses within a thick elastic plate overlying a viscoelastic or fluid half-space. The 3-D stress perturbation is resolved into normal and shear stresses on plate boundary fault planes of known orientation so that Coulomb stress perturbations can be calculated. In the absence of complete paleoseismic indicators that span the time since the Last Glacial Maximum, we investigate the possibility that the seismic cycle of coastal plate boundary faults was affected by stress perturbations due to the change in sea level. Coulomb stress on onshore transform faults, such as the San Andreas and Alpine faults, is increased by up to 1-1.5 MPa, respectively, promoting failure primarily through a reduction in normal stress. These stress perturbations may perceptibly alter the seismic cycle of major plate boundary faults, but such effects are more likely to be observed on nearby secondary faults with a lower tectonic stress accumulation rate. In the specific instance of rapid sea level rise at the Black Sea, the seismic cycle of the nearby North Anatolian fault was likely significantly advanced.

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Palaeoseismology of the Vilariça Segment of the Manteigas-Bragança Fault in northeastern Portugal

Cited by 38 publications

References 23 publications

Contribution of active faults in the intraplate area of Iberia to seismic hazard: The Alentejo-Plasencia Fault

Contribution of active faults in the intraplate area of Iberia to seismic hazard: The Alentejo-Plasencia Fault

Seismicity and potencially active faults in the Northwest and Central-West Iberian Peninsula

Ocean loading effects on stress at near shore plate boundary fault systems

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