5.1 Timing, Architecture, and Kinematics of Deformation sopra the Soddo Settore

5.1 Timing, Architecture, and Kinematics of Deformation sopra the Soddo Settore

The plan view architecture of the Soddo margin is characterized by verso typical array of sigmoidal, right-stepping en-echelon normal or oblique faults (Figure 5)

Per order preciso better characterize the distribution of vents per the distretto and sicuro better define their relations with faults, we have mapped vent alignments and assessed their reliability according puro the procedure illustrated durante Paulsen and Wilson [ 2010 ]. Vent mapping has been performed on available astro images (Landsat TM, Aster, Google Earth imagery), digital elevation models (DEMs; SRTM, Aster), and aerial photos. Durante particular, vent alignments have been mapped on the basis of the spatial distribution of vents as well as their shapes (vent elongation provides a critical parameter onesto group celibe vents into an alignment). Reliability of vent alignments has been defined according sicuro parameters such as number of vents, number and characteristics of elongate vents (vents are considered elongate when the ratio between the lengths of the maximum and minimum axes is >1.2), norma deviation from per best fit line, etc. [see Paulsen and Wilson, 2010 ]. The result of this analysis is illustrated durante Table 3 and mediante the graph of Figure 12d, where the azimuthal distribution of elongate vent long axis has also been reported. The distribution of both vent alignments and elongate vent long axis shows verso main peak at N20°–25°Ancora, indicating a striking correspondence with the movimento of the border faults mediante the reparto (compare Figure 12d with Figure 5c) and thus strengthening the close relations between faulting and volcanism. Preciso complete the analysis, we have also calculated the azimuthal distribution of cone breaching, whose results are shown sopra the graph of Figure 12e. This analysis indicates that the inclinazione of cone breaching tends esatto parallelize vent alignments (as well as the andamento of border faults), with a minor peak orthogonal puro this latter andamento. Both observations are sopra agreement with theoretical predictions [Tibaldi, 1995 ].

  • verso Adapted from Paulsen and Wilson . Latitude and longitude of alignment locations assume WGS84 datum.
  • b B, basalts; R, rhyolites.
  • c Verso vent is considered elongated when the ratio between the lengths of the maximum and minimum axes of the best fit ellipse matching the mapped shape of the vent is>1.2.
  • d Fissure ridge.
  • anche Reliability grade: A> B> C> D.

5 Tete-a-tete

The collected tempo illustrate significant Late Pleistocene-Holocene tectonic activity of the western margin close preciso Soddo, where radiometric dating of faulted material indicates Late Pleistocene-Holocene (post-30 ka) fault activity. This supports inferences based on analysis of historical seismicity [Gouin, 1979 ; Keir et al., 2006 ], morphotectonic investigations [Boccaletti et al., 1998 ], and recent Navigatore tempo [Kogan et al., 2012 ] suggesting active deformation along the western rift margin of the Southern MER. Although not quantifiable because of the lack of subsurface information, deformation is apparently subordinate at the rift axis, where the recent tectono-magmatic activity is likely related onesto incipient WFB faulting as hypothesized for the Central MER [Agostini et al., 2011a ]. These findings support https://datingranking.net/it/amino-review/ models that predict a transition from axial tectono-magmatic deformation durante the Northern MER onesto marginal deformation durante the Central and Southern MER, sopra turn indicating an along-axis, north to south decrease in rift maturity durante the MER [anche.g., Hayward and Ebinger, 1996 ; Corti, 2009 ; Agostini et al., 2011a ].

The rift margin at Soddo is characterized by the lack of a major rift escarpment with a gentle transition between the rift floor and the plateau accommodated by numerous faults (Figure 4) with limited lateral extent (maximum length in the range of a few kilometers) and small vertical offset (typically <100>1000 m) give rise to prominent fault escarpments. Comparison of this architecture with the deformation resulting from analog models of rifting indicates that the fault pattern has been controlled by a sub-E-W (N95°E to N100°E) extension direction, resulting in an oblique extension with respect to the roughly NE-SW-trending rift. This well accords with inversion of fault slip data collected on faults with Pleistocene-Holocene activity, which indicates a N105°E-directed extension (Figure 3), with local variations in the paleostress field likely resulting from stress reorientations and/or influence of volcanic activity [e.g., Acocella et al., 2011 ]. These results are strikingly similar to recent GPS data from the Southern MER [Kogan et al., 2012 ], which also indicate a current N100°E-directed extension at the latitude of Arba Minch (

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