Evaluación Paleosísmica Del Segmento San Felipe De La Falla De Boconó (Venezuela Noroccidental): ¿responsable Del Terremoto Del 26 De Marzo De 1812?

Audemard, Franck; Franck, Alice

doi:10.18273/revbol.v38n1-2016007

Cited by 7 publications

(6 citation statements)

References 15 publications

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“…An alternative explanation for this has been sought in the possible condition of fault creep along the short cut fault that has some supporting evidence in the common presence of fractures and cracks oriented perpendicular to the fault trace seen at surface and in buildings within the zone of fault shear along the western limit of the town of Algeciras. On the other hand, the morphotectonic expression of the main branch of Algeciras Fault compares with the Boconó Fault in Venezuela that has a well-established slip rate in the order of 10 Quaternary mm/y (Audemard, 2014(Audemard, , 2016Audemard et al, 2006;Pousse-Beltran et al, 2017). Likewise, fault slip rate data for faults of the Ecuadorian side of the transform system have yielded similar results (Alvarado et al, 2016;Baize et al, 2014;Tibaldi & Ferrari, 1991;Tibaldi et al, 2007).…”

Section: Resultsmentioning

confidence: 87%

“…This crustal block is in the process of tectonic escape to the NNE as first suggested by Pennington (1981) and later by others like Audemard (1993), Egbue & Kellogg (2010), Freymueller et al (1993, Kellogg & Vega, 1995, Taboada et al (2000, Tibaldi & Ferrari (1991), Trenkamp et al (2002), andWitt et al (2006). This escape movement has been demonstrated in the plots of Global Position System (GPS) velocity vectors established during the CASA project (Freymueller et al, 1993;Kellogg & Vega, 1995) and, more recently, has been corroborated by the densified network of permanent GPS/ GNSS stations of the GeoRED project, which firmly has established a NNE movement of 8.6 mm/y (Figure 3; Mora-Páez et al, 2002, 2016, 2019. The crustal block escape is the result of the interaction of the three major tectonic plates of Nazca, Caribbean, and South America, complemented by the collision of the Panamá-Baudó Arc (Figure 1).…”

Section: Regional Tectonic Settingmentioning

confidence: 73%

“…Nevertheless, the up-to date pattern of velocity vectors established during the GeoRED project points universally to movement of the block in a NNE direction at a velocity of 8.6 mm/y (Figure 3; Mora-Páez et al, 2016, 2019. The Guaicáramo system runs along the foothills of the Eastern Cordillera and consists predominantly of east verging thrust and stacked thrust systems that are the mark of a foreland fold and thrust belt (Bayona et al, 2008;Diederix et al, 2010;García et al, 2011;Mora et al, 2010), but always maintains a dextral strike-slip component as has been observed in the field (Diederix et al, 2010) and is also evident in the pattern of GPS velocity vectors established during the GeoRED project (Figure 3; Mora-Páez et al, 2002, 2016, 2019. The Guaicáramo Fault System makes an abrupt double right angle bend north of the town of Tame in the northeast over a distance of 150 km to resume its NE strike at the town of Cúcuta and continues as the Boconó Fault that follows the length of the Mérida Andes in Venezuela (Audemard & Audemard, 2002;Audemard et al, 2005Audemard et al, , 2006.…”

Section: Regional Tectonic Settingmentioning

confidence: 87%

“…The slightly more ENE orientation of the velocity field of GPS vectors that can be observed north of latitude 7° N, suggests the influence of a W-E push that add an E-W component to the NNE movement of the NAB (Figure 3; Mora-Páez et al, 2019). The consensus opinion is that the oblique Nazca Plate convergence with South America is the controlling factor for slip partitioning and the escape of the NAB and whatever the precise date for the beginning of the displacement of the NAB by means of movement of the fault system, a fact is that the AFS in all its morphological characteristics provides us with convincing evidence of recent and ongoing dextral strike-slip movement, that until now has not been possible to be quantified, but could well be in the range of 10 mm/y in analogy to the values for slip rate obtained of its trajectories in Ecuador (Alvarado et al, 2016;Baize et al, 2014;Ego et al, 1996;Nocquet et al, 2014; 1992; Tibaldi et al, 2007) and Venezuela (Audemard, 2014(Audemard, , 2016Pousse-Beltran et al, 2017).…”

Section: Quaternarymentioning

confidence: 90%

“…Particularly in the sector between the village of Algeciras in the north and Pitalito in the south, most of the movement of the fault system is concentrated along this main branch. This has resulted in an outstanding morphological expression on the DEM imagery and also on aerial photos that compare with the well-known and well-studied Boconó Fault in Venezuela (e.g., Audemard, 2016;Audemard & Audemard, 2002;Audemard et al, 2005Audemard et al, , 2006Pousse-Beltran et al, 2017). The width of the fault belt of the AFS varies in this sector between 25 and 40 km.…”

Section: The Algeciras Fault Systemmentioning

confidence: 94%

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Chapter 12

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2019

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The Algeciras Fault System, of predominant dextral strike-slip displacement, is part of the major interplate transform fault system, known in Ecuador, Colombia, and Venezuela as the Eastern Frontal Fault System. This unique transform deformation belt connects the Nazca Plate in the Gulf of Guayaquil in Ecuador with the Caribbean Plate along the coast of Venezuela. Its dextral strike-slip displacement along the eastern boundary of the North Andean Block facilitates tectonic escape of this microplate in a NNE direction. The Algeciras Fault System constitutes the southern half of this transform belt in Colombia, the northern half runs along the foothills of the Eastern Cordillera and is known as the Guaicáramo Thrust Fault System that connects to the Boconó Fault in Venezuela. This relation underlines the significance of the Algeciras Fault System as the major active fault system in continental Colombia that plays a fundamental role in the geodynamics of the northern Andes. So far, the study of this fault system has established a notable degree of fault activity which has been corroborated by data of historic seismicity and velocity vector data of satellite geodesy obtained in recent years by the Grupo de Investigación en Geodesia Satelital of Servicio Geológico Colombiano. The presence of a series of pull-apart basins and the occurrence of monogenetic alkali basaltic volcanism within the realm of the Algeciras Fault System point to transtensional stress regimes that could possibly relate to mantle processes. Knowledge of this fault system has also important implications for seismic hazards that affect considerable parts of the country and pose a particular threat to the capital city. This chapter narrates the history of the actual state of knowledge that reflects the initial stage of a more profound study of the active tectonics of this great and important fault system.

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Section: Resultsmentioning

confidence: 87%

Section: Regional Tectonic Settingmentioning

confidence: 73%

Section: Regional Tectonic Settingmentioning

confidence: 87%

Section: Quaternarymentioning

confidence: 90%

Section: The Algeciras Fault Systemmentioning

confidence: 94%

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Chapter 12

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2019

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Pleistocene slip rates on the Boconó fault along the North Andean Block plate boundary, Venezuela

et al. 2017

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The Boconó fault is a strike‐slip fault lying between the North Andean Block and the South American plate which has triggered at least five Mw > 7 historical earthquakes in Venezuela. The North Andean Block is currently moving toward NNE with respect to a stable South American plate. This relative displacement at ~12 mm yr−1 in Venezuela (within the Maracaibo Block) was measured by geodesy, but until now the distribution and rates of Quaternary deformation have remained partially unclear. We used two alluvial fans offset by the Boconó fault (Yaracuy Valley) to quantify slip rates, by combining 10Be cosmogenic dating with measurements of tectonic displacements on high‐resolution satellite images (Pleiades). Based upon a fan dated at >79 ka and offset by 1350–1580 m and a second fan dated at 120–273 ka and offset by 1236–1500 m, we obtained two Pleistocene rates of 5.0–11.2 and <20.0 mm yr−1, consistent with the regional geodesy. This indicates that the Boconó fault in the Yaracuy Valley accommodates 40 to 100% of the deformation between the South American plate and the Maracaibo Block. As no aseismic deformation was shown by interferometric synthetic aperture radar analysis, we assume that the fault is locked since the 1812 event. This implies that there is a slip deficit in the Yaracuy Valley since the last earthquake ranging from ~1 to 4 m, corresponding to a Mw 7–7.6 earthquake. This magnitude is comparable to the 1812 earthquake and to other historical events along the Boconó fault.

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