TY  - JOUR
A1  - Rajaonarison, Tahiry A.
A1  - Stamps, D. Sarah
A1  - Fishwick, Stewart
A1  - Brune, Sascha
A1  - Glerum, Anne
A1  - Hu, Jiashun
T1  - Numerical modeling of mantle flow beneath Madagascar to constrain upper mantle rheology beneath continental regions
JF  - Journal of geophysical research : Solid earth
N2  - Over the past few decades, azimuthal seismic anisotropy measurements have been widely used proxy to study past and present-day deformation of the lithosphere and to characterize convection in the mantle. Beneath continental regions, distinguishing between shallow and deep sources of anisotropy remains difficult due to poor depth constraints of measurements and a lack of regional-scale geodynamic modeling. Here, we constrain the sources of seismic anisotropy beneath Madagascar where a complex pattern cannot be explained by a single process such as absolute plate motion, global mantle flow, or geology. We test the hypotheses that either Edge-Driven Convection (EDC) or mantle flow derived from mantle wind interactions with lithospheric topography is the dominant source of anisotropy beneath Madagascar. We, therefore, simulate two sets of mantle convection models using regional-scale 3-D computational modeling. We then calculate Lattice Preferred Orientation that develops along pathlines of the mantle flow models and use them to calculate synthetic splitting parameters. Comparison of predicted with observed seismic anisotropy shows a good fit in northern and southern Madagascar for the EDC model, but the mantle wind case only fits well in northern Madagascar. This result suggests the dominant control of the measured anisotropy may be from EDC, but the role of localized fossil anisotropy in narrow shear zones cannot be ruled out in southern Madagascar. Our results suggest that the asthenosphere beneath northern and southern Madagascar is dominated by dislocation creep. Dislocation creep rheology may be dominant in the upper asthenosphere beneath other regions of continental lithosphere.
KW  - seismic anisotropy
KW  - edge-driven convection
KW  - mantle flow modeling
KW  - lattice preferred orientations
KW  - lithosphere-mantle wind interactions
KW  - splitting parameters
Y1  - 2019
U6  - https://doi.org/10.1029/2019JB018560
SN  - 2169-9313
SN  - 2169-9356
VL  - 125
IS  - 2
PB  - American Geophysical Union
CY  - Washington
ER  - 
TY  - GEN
A1  - Sippel, Judith
A1  - Meeßen, Christian
A1  - Cacace, Mauro
A1  - Mechie, James
A1  - Fishwick, Stewart
A1  - Heine, Christian
A1  - Scheck-Wenderoth, Magdalena
A1  - Strecker, Manfred
T1  - The Kenya rift revisited
BT  - insights into lithospheric strength through data-driven 3-D gravity and thermal modelling
T2  - Postprints der Universität Potsdam : Mathematisch Naturwissenschaftliche Reihe
N2  - We present three-dimensional (3-D) models that describe the present-day thermal and rheological state of the lithosphere of the greater Kenya rift region aiming at a better understanding of the rift evolution, with a particular focus on plume-lithosphere interactions. The key methodology applied is the 3-D integration of diverse geological and geophysical observations using gravity modelling. Accordingly, the resulting lithospheric-scale 3-D density model is consistent with (i) reviewed descriptions of lithological variations in the sedimentary and volcanic cover, (ii) known trends in crust and mantle seismic velocities as revealed by seismic and seismological data and (iii) the observed gravity field. This data-based model is the first to image a 3-D density configuration of the crystalline crust for the entire region of Kenya and northern Tanzania. An upper and a basal crustal layer are differentiated, each composed of several domains of different average densities. We interpret these domains to trace back to the Precambrian terrane amalgamation associated with the East African Orogeny and to magmatic processes during Mesozoic and Cenozoic rifting phases. In combination with seismic velocities, the densities of these crustal domains indicate compositional differences. The derived lithological trends have been used to parameterise steady-state thermal and rheological models. These models indicate that crustal and mantle temperatures decrease from the Kenya rift in the west to eastern Kenya, while the integrated strength of the lithosphere increases. Thereby, the detailed strength configuration appears strongly controlled by the complex inherited crustal structure, which may have been decisive for the onset, localisation and propagation of rifting.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 644 
KW  - east-african rift
KW  - cenozoic Turkana depression
KW  - seismic velocity structure
KW  - Northern Kenya
KW  - upper-mantle
KW  - Mozambique belt
KW  - continental lithosphere
KW  - crustal structure
KW  - structure beneath
KW  - wave tomography
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-418221
SN  - 1866-8372
IS  - 644
SP  - 45
EP  - 81
ER  - 
TY  - JOUR
A1  - Sippel, Judith
A1  - Meessen, Christian
A1  - Cacace, Mauro
A1  - Mechie, James
A1  - Fishwick, Stewart
A1  - Heine, Christian
A1  - Scheck-Wenderoth, Magdalena
A1  - Strecker, Manfred
T1  - The Kenya rift revisited
BT  - insights into lithospheric strength through data-driven 3-D gravity and thermal modelling
JF  - Solid earth
N2  - We present three-dimensional (3-D) models that describe the present-day thermal and rheological state of the lithosphere of the greater Kenya rift region aiming at a better understanding of the rift evolution, with a particular focus on plume-lithosphere interactions. The key methodology applied is the 3-D integration of diverse geological and geophysical observations using gravity modelling. Accordingly, the resulting lithospheric-scale 3-D density model is consistent with (i) reviewed descriptions of lithological variations in the sedimentary and volcanic cover, (ii) known trends in crust and mantle seismic velocities as revealed by seismic and seismological data and (iii) the observed gravity field. This data-based model is the first to image a 3-D density configuration of the crystalline crust for the entire region of Kenya and northern Tanzania. An upper and a basal crustal layer are differentiated, each composed of several domains of different average densities. We interpret these domains to trace back to the Precambrian terrane amalgamation associated with the East African Orogeny and to magmatic processes during Mesozoic and Cenozoic rifting phases. In combination with seismic velocities, the densities of these crustal domains indicate compositional differences. The derived lithological trends have been used to parameterise steady-state thermal and rheological models. These models indicate that crustal and mantle temperatures decrease from the Kenya rift in the west to eastern Kenya, while the integrated strength of the lithosphere increases. Thereby, the detailed strength configuration appears strongly controlled by the complex inherited crustal structure, which may have been decisive for the onset, localisation and propagation of rifting.
Y1  - 2017
U6  - https://doi.org/10.5194/se-8-45-2017
SN  - 1869-9510
SN  - 1869-9529
VL  - 8
SP  - 45
EP  - 81
PB  - Copernicus
CY  - Göttingen
ER  -