Lithospheric Boundaries and Upper Mantle Structure Beneath Southern Africa Imaged by <i>P</i> and <i>S</i> Wave Velocity Models

White-Gaynor, A.; Nyblade, A.; Durrheim, Raymond; Raveloson, R.; Meijde, M. van der; Fadel, Islam; Paulssen, Hanneke; Kwadiba, M. T. O.; Ntibinyane, Onkgopotse; Titus, N.; Sitali, M.

doi:10.1029/2020gc008925

Cited by 12 publications

(21 citation statements)

References 77 publications

(143 reference statements)

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“…In other words, our models show that the northern boundary of the greater Kalahari Craton lies along the southern margin of the Damara Belt, and that the western boundary lies along the eastern margin of the Gariep and Namaqua-Natal belts. This finding is consistent with body wave tomography models showing a similar transition in P wave and S wave velocity structure across these terrane boundaries (Ortiz et al, 2019;White-Gaynor et al, 2020), and also with MT studies (Miensopust et al, 2011;Muller et al, 2009).…”

Section: Discussionsupporting

confidence: 90%

Shear‐Wave Velocity Structure of the Southern African Upper Mantle: Implications for Craton Structure and Plateau Uplift

White-Gaynor

Nyblade

Durrheim

et al. 2021

Geophysical Research Letters

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We present a 3D shear‐wave velocity model of the southern African upper mantle developed using 30–200 s period Rayleigh waves recorded on regional seismic networks spanning the subcontinent. The model shows high velocities (∼4.7–4.8 km/s) at depths of 50–250 km beneath the Archean nucleus and several surrounding Paleoproterozoic and Mesoproterozoic terranes, placing the margin of the greater Kalahari Craton along the southern boundary of the Damara Belt and the eastern boundaries of the Gariep and Namaqua‐Natal belts. At depths ≥250 km, there is little difference in velocities beneath the craton and off‐craton regions, suggesting that the cratonic lithosphere extends to depths of about 200–250 km. Upper mantle velocities beneath uplifted areas of southern Africa are higher than the global average and significantly higher than beneath eastern Africa, indicating there that is little thermal modification of the upper mantle present today beneath the Southern African Plateau.

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Section: Discussionsupporting

confidence: 90%

Shear‐Wave Velocity Structure of the Southern African Upper Mantle: Implications for Craton Structure and Plateau Uplift

White-Gaynor

Nyblade

Durrheim

et al. 2021

Geophysical Research Letters

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“…This low velocity anomaly in the uppermost mantle may be interpreted as the mantle source of fluids. The low velocity anomaly beneath the ORZ was also found in several other (lower resolution) tomographic P and S wave velocity models (Ortiz et al, 2019;White-Gaynor et al, 2020), and may be related to decompression melting caused by lithospheric thinning in response to tensional stresses (Yu et al, 2017). The normal-faulting focal mechanisms are consistent with the tensional stress regime that is required for such a scenario.…”

Section: Discussionsupporting

confidence: 66%

Rifting of the Kalahari Craton Through Botswana? New Seismic Evidence

et al. 2022

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“…Similarly, Proterozoic terranes assembled near the Archean cratons do not show consistent characteristics and architectures that would provide a simple relationship between lithospheric thickness, age, and composition from the electrical conductivity distribution. The south‐central Rehoboth Terrane, for instance, demonstrates lower resistivities ( K 2 ‐ K 3 , Figure 3b) and higher velocity bodies (White‐Gaynor et al., 2020). In contrast, the Gibeon area, which includes one of the clusters of Cretaceous kimberlitic volcanism, is imaged as a highly resistive region (Figure 3f), with relatively lower velocities (White‐Gaynor et al., 2020).…”

Section: Discussionmentioning

confidence: 97%

“…The south-central Rehoboth Terrane, for instance, demonstrates lower resistivities (K 2 -K 3 , Figure 3b) and higher velocity bodies (White-Gaynor et al, 2020). In contrast, the Gibeon area, which includes one of the clusters of Cretaceous kimberlitic volcanism, is imaged as a highly resistive region (Figure 3f), with relatively lower velocities (White-Gaynor et al, 2020). Similarly, the northern end of the Rehoboth Terrane and adjacent Ghanzi-Chobe belt possibly shows the greatest depths at which 1,000 Ωm resistivity is observed (Figure 12b).…”

Section: Resistivity Of Archean Proterozoic Depleted and Metasomatize...mentioning

confidence: 99%

Probing the Southern African Lithosphere With Magnetotellurics: 2. Linking Electrical Conductivity, Composition, and Tectonomagmatic Evolution

et al. 2022

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The tectonic history of southern Africa includes Archean craton formation, multiple episodes of subduction and rifting and some of the world's most significant magmatic events. These processes left behind a compositional trail that can be observed in xenoliths and measured by geophysical methods. The abundance of kimberlites in southern Africa makes it an ideal place to test and calibrate mantle geophysical interpretations that can then be applied to less well‐constrained regions. Magnetotellurics (MT) is a particularly useful tool for understanding tectonic history because electrical conductivity is sensitive to temperature, bulk composition, accessory minerals, and rock fabric. We produced three‐dimensional MT models of the southern African mantle taken from the SAMTEX MT data set, mapped the properties of ∼36,000 garnet xenocrysts from Group I kimberlites, and compared the results. We found that depleted regions of the mantle are uniformly associated with high electrical resistivities. The conductivity of fertile regions is more complex and depends on the specific tectonic and metasomatic history of the region, including the compositions of metasomatic fluids or melts and the emplacement of metasomatic minerals. The mantle beneath the ∼2.05 Ga Bushveld Complex is highly conductive, probably caused by magmas flowing along a lithospheric weakness zone and precipitating interconnected, conductive accessory minerals such as graphite and sulfides. Kimberlites tend to be emplaced near the edges of the cratons where the mantle below 100 km depth is not highly resistive. Kimberlites avoid strong mantle conductors, suggesting a systematic relationship between their emplacement and mantle composition.

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Lithospheric Boundaries and Upper Mantle Structure Beneath Southern Africa Imaged by P and S Wave Velocity Models

Cited by 12 publications

References 77 publications

Shear‐Wave Velocity Structure of the Southern African Upper Mantle: Implications for Craton Structure and Plateau Uplift

Shear‐Wave Velocity Structure of the Southern African Upper Mantle: Implications for Craton Structure and Plateau Uplift

Rifting of the Kalahari Craton Through Botswana? New Seismic Evidence

Probing the Southern African Lithosphere With Magnetotellurics: 2. Linking Electrical Conductivity, Composition, and Tectonomagmatic Evolution

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