Present‐day kinematics of the East African Rift

Saria, E.; Calais, E.; Stamps, D. S.; Delvaux, Damien; Hartnady, Chris

doi:10.1002/2013jb010901

Cited by 302 publications

(368 citation statements)

References 84 publications

(150 reference statements)

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“…As shown by Kogan et al (2012) and Birhanu et al (2016), the stations located in the southeastern part of the network (BILA, DAMY, ARBK and BKOB) show NE-trending horizontal velocities. That differs from the N090-110 • E-trending velocity expected by the present-day plate models (Déprez et al 2013(Déprez et al , 2015Saria et al 2013Saria et al , 2014Fig. 4).…”

Section: The Northern Part Of the Main Ethiopian Riftcontrasting

confidence: 57%

“…Regarding the GPS data, only the horizontal baseline between the sites of OLAB and BKOB, located ∼50 and ∼160 km away from the rift axis, respectively, can be used to quantify the extension rate. Projected along a ∼N100 • E trending profile, that is perpendicular to the rift axis, the opening rate is ∼3 mm yr -1 , which is lower than the opening rate predicted by the plate motion models at this latitude of the EAR (∼5 mm yr -1 along the N100 • E direction, Chu & Gordon 1999;Déprez et al 2013Déprez et al , 2015Saria et al 2014). As shown by Kogan et al (2012) and Birhanu et al (2016), the stations located in the southeastern part of the network (BILA, DAMY, ARBK and BKOB) show NE-trending horizontal velocities.…”

Section: The Northern Part Of the Main Ethiopian Riftmentioning

confidence: 65%

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Current deformation in Central Afar and triple junction kinematics deduced from GPS and InSAR measurements

Doubre¹,

Déprez²,

Masson³

et al. 2016

Geophys. J. Int.

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S U M M A R YKinematics of divergent boundaries and Rift-Rift-Rift junctions are classically studied using long-term geodetic observations. Since significant magma-related displacements are expected, short-term deformation provides important constraints on the crustal mechanisms involved both in active rifting and in transfer of extensional deformation between spreading axes. Using InSAR and GPS data, we analyse the surface deformation in the whole Central Afar region in detail, focusing on both the extensional deformation across the Quaternary magmato-tectonic rift segments, and on the zones of deformation transfer between active segments and spreading axes. The largest deformation occurs across the two recently activated Asal-Ghoubbet (AG) and Manda Hararo-Dabbahu (MH-D) magmato-tectonic segments with very high strain rates, whereas the other Quaternary active segments do not concentrate any large strain, suggesting that these rifts are either sealed during interdyking periods or not mature enough to remain a plate boundary. Outside of these segments, the GPS horizontal velocity field shows a regular gradient following a clockwise rotation of the displacements from the Southeast to the East of Afar, with respect to Nubia. Very few shallow creeping structures can be identified as well in the InSAR data. However, using these data together with the strain rate tensor and the rotations rates deduced from GPS baselines, the present-day strain field over Central Afar is consistent with the main tectonic structures, and therefore with the long-term deformation. We investigate the current kinematics of the triple junction included in our GPS data set by building simple block models. The deformation in Central Afar can be described by adding a central microblock evolving separately from the three surrounding plates. In this model, the northern block boundary corresponds to a deep EW-trending trans-tensional dislocation, locked from the surface to 10-13 km and joining at depth the active spreading axes of the Red Sea and the Aden Ridge, from AG to MH-D rift segments. Over the long-term, this plate configuration could explain the presence of the en-échelon magmatic basins and subrifts. However, the transient behaviour of the spreading axes implies that the deformation in Central Afar evolves depending on the availability of magma supply within the well-established segments.

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Section: The Northern Part Of the Main Ethiopian Riftcontrasting

confidence: 57%

Section: The Northern Part Of the Main Ethiopian Riftmentioning

confidence: 65%

Current deformation in Central Afar and triple junction kinematics deduced from GPS and InSAR measurements

Doubre¹,

Déprez²,

Masson³

et al. 2016

Geophys. J. Int.

View full text Add to dashboard Cite

show abstract

“…Furthermore, data from a single GPS within the Malawi Rift estimate a plate-opening velocity of ca. 1 mm yr −1 (Saria et al 2014).…”

Section: T E C T O N I C S E T T I N Gmentioning

confidence: 97%

Surface wave imaging of the weakly extended Malawi Rift from ambient-noise and teleseismic Rayleigh waves from onshore and lake-bottom seismometers

Accardo

Gaherty

Shillington

et al. 2017

Geophysical Journal International

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“…The NE-trending Eyasi-Wembere rift arm cross-cuts the east of the suture of the Pan-African-Archaean boundary and continues further SW across the deeply rooted craton. From geodetic data, direction of plate separation in East Africa are estimated at 4 mm yr −1 in an approximately E-W direction (Saria et al 2014).…”

Section: G E O L O G I C a L S E T T I N Gmentioning

confidence: 99%

Lithospheric low-velocity zones associated with a magmatic segment of the Tanzanian Rift, East Africa

Plasman¹,

Tiberi

Ebinger

et al. 2017

Geophysical Journal International

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Present‐day kinematics of the East African Rift

Cited by 302 publications

References 84 publications

Current deformation in Central Afar and triple junction kinematics deduced from GPS and InSAR measurements

Current deformation in Central Afar and triple junction kinematics deduced from GPS and InSAR measurements

Surface wave imaging of the weakly extended Malawi Rift from ambient-noise and teleseismic Rayleigh waves from onshore and lake-bottom seismometers

Lithospheric low-velocity zones associated with a magmatic segment of the Tanzanian Rift, East Africa

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