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Seismic anisotropy of the upper mantle below Western rift, East Africa

Seismic anisotropy of the upper mantle below Western rift, East Africa
Seismic anisotropy of the upper mantle below Western rift, East Africa
Although the East African rift system formed in cratonic lithosphere above a large‐scale mantle upwelling, some sectors have voluminous magmatism, while others have isolated, small‐volume eruptive centers. We conduct teleseismic shear wave splitting analyses on data from 5 lake‐bottom seismometers and 67 land stations in the Tanganyika‐Rukwa‐Malawi rift zone, including the Rungwe Volcanic Province (RVP), and from 5 seismometers in the Kivu rift and Virunga Volcanic Province, to evaluate rift‐perpendicular strain, rift‐parallel melt intrusion, and regional flow models for seismic anisotropy patterns beneath the largely amagmatic Western rift. Observations from 684 SKS and 305 SKKS phases reveal consistent patterns. Within the Malawi rift south of the RVP, fast splitting directions are oriented northeast with average delays of ~1 s. Directions rotate to N‐S and NNW north of the volcanic province within the reactivated Mesozoic Rukwa and southern Tanganyika rifts. Delay times are largest (~1.25 s) within the Virunga Volcanic Province. Our work combined with earlier studies shows that SKS‐splitting is rift parallel within Western rift magmatic provinces, with a larger percentage of null measurements than in amagmatic areas. The spatial variations in direction and amount of splitting from our results and those of earlier Western rift studies suggest that mantle flow is deflected by the deeply rooted cratons. The resulting flow complexity, and likely stagnation beneath the Rungwe province, may explain the ca. 17 Myr of localized magmatism in the weakly stretched RVP, and it argues against interpretations of a uniform anisotropic layer caused by large‐scale asthenospheric flow or passive rifting.
2169-9356
Tepp, G.
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Ebinger, C.J.
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Zal, H.
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Gallacher, R.
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Accardo, N.J.
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Shillington, D.J.
2f126bf1-76b6-4a51-aefd-81a680c4476b
Gaherty, J.
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Keir, Derek
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Nyblade, A.A.
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Mbogoni, G.J.
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Chindandali, P.R.N.
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Ferdinand-Wambura, R.
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Mulibo, G.D.
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Kamihanda, G.
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Tepp, G.
f8091e94-df06-4b93-8c3b-2c205e71996b
Ebinger, C.J.
aedfe44b-76f6-4882-9522-0079fba9feda
Zal, H.
32ef3097-84db-4cbc-b463-e0c50cf2e42f
Gallacher, R.
3d4aa45c-babe-4164-bee2-fc49afda41a7
Accardo, N.J.
d3f5616f-bf5e-4801-8106-4e133a5c9c2b
Shillington, D.J.
2f126bf1-76b6-4a51-aefd-81a680c4476b
Gaherty, J.
79bb628a-e714-4bcd-9f63-cdabf6236aa8
Keir, Derek
5616f81f-bf1b-4678-a167-3160b5647c65
Nyblade, A.A.
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Mbogoni, G.J.
654a2bf6-4175-46af-80fa-60d510dda92f
Chindandali, P.R.N.
7048a07c-13ca-4c96-8837-1697b73f417d
Ferdinand-Wambura, R.
3cdecddd-9cea-4a06-a7d3-80bf6d7bbf27
Mulibo, G.D.
0839eca6-bc4b-40bb-9403-45140ab229f4
Kamihanda, G.
46420070-5e11-4024-91e5-6c0caf964354

Tepp, G., Ebinger, C.J., Zal, H., Gallacher, R., Accardo, N.J., Shillington, D.J., Gaherty, J., Keir, Derek, Nyblade, A.A., Mbogoni, G.J., Chindandali, P.R.N., Ferdinand-Wambura, R., Mulibo, G.D. and Kamihanda, G. (2018) Seismic anisotropy of the upper mantle below Western rift, East Africa. Journal of Geophysical Research: Solid Earth. (doi:10.1029/2017JB015409).

Record type: Article

Abstract

Although the East African rift system formed in cratonic lithosphere above a large‐scale mantle upwelling, some sectors have voluminous magmatism, while others have isolated, small‐volume eruptive centers. We conduct teleseismic shear wave splitting analyses on data from 5 lake‐bottom seismometers and 67 land stations in the Tanganyika‐Rukwa‐Malawi rift zone, including the Rungwe Volcanic Province (RVP), and from 5 seismometers in the Kivu rift and Virunga Volcanic Province, to evaluate rift‐perpendicular strain, rift‐parallel melt intrusion, and regional flow models for seismic anisotropy patterns beneath the largely amagmatic Western rift. Observations from 684 SKS and 305 SKKS phases reveal consistent patterns. Within the Malawi rift south of the RVP, fast splitting directions are oriented northeast with average delays of ~1 s. Directions rotate to N‐S and NNW north of the volcanic province within the reactivated Mesozoic Rukwa and southern Tanganyika rifts. Delay times are largest (~1.25 s) within the Virunga Volcanic Province. Our work combined with earlier studies shows that SKS‐splitting is rift parallel within Western rift magmatic provinces, with a larger percentage of null measurements than in amagmatic areas. The spatial variations in direction and amount of splitting from our results and those of earlier Western rift studies suggest that mantle flow is deflected by the deeply rooted cratons. The resulting flow complexity, and likely stagnation beneath the Rungwe province, may explain the ca. 17 Myr of localized magmatism in the weakly stretched RVP, and it argues against interpretations of a uniform anisotropic layer caused by large‐scale asthenospheric flow or passive rifting.

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Tepp_et_al-2018-Journal_of_Geophysical_Research%3A_Solid_Earth - Accepted Manuscript
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More information

Accepted/In Press date: 28 May 2018
e-pub ahead of print date: 4 June 2018
Published date: July 2018

Identifiers

Local EPrints ID: 422021
URI: http://eprints.soton.ac.uk/id/eprint/422021
DOI: doi:10.1029/2017JB015409
ISSN: 2169-9356
PURE UUID: 2cd2b772-083f-453b-a63f-eeada6a9c36e
ORCID for Derek Keir: ORCID iD orcid.org/0000-0001-8787-8446

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Date deposited: 12 Jul 2018 16:31
Last modified: 16 Mar 2024 04:06

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Contributors

Author: G. Tepp
Author: C.J. Ebinger
Author: H. Zal
Author: R. Gallacher
Author: N.J. Accardo
Author: D.J. Shillington
Author: J. Gaherty
Author: Derek Keir ORCID iD
Author: A.A. Nyblade
Author: G.J. Mbogoni
Author: P.R.N. Chindandali
Author: R. Ferdinand-Wambura
Author: G.D. Mulibo
Author: G. Kamihanda

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