Insights into extensional processes during magma assisted rifting: Evidence from aligned scoria cones
Insights into extensional processes during magma assisted rifting: Evidence from aligned scoria cones
Mechanical and magmatic processes exert first-order control on the architecture and evolution of rifts. As a continental rift develops towards a new oceanic spreading centre, extension that is initially accommodated in a broad zone of faulting and ductile stretching must transition towards a narrow zone of focused magmatic intrusion. The Main Ethiopian Rift (MER), part of the East African Rift System, is an ideal location to study this transition because it captures rifting processes during continental breakup. In this contribution we synthesise geochemical data from scoria cones in the Wonji Fault Belt (WFB) and Silti-Debre Zeyit Fault Zone (SDFZ) in the MER to provide new constraints on the development of mantle melting columns and magmatic plumbing systems since the onset of rifting. We utilize the extensive geophysical and geochemical databases, collected in the Ethiopian Rift, to show that geochemical evidence of heterogeneity in the depth of the mantle melting column which produced Quaternary rift basalts correlates with lithospheric structure. When combined with existing observations of asymmetry across the rift in terms of depth of melting column and magmatic plumbing systems, it is evident that the mechanical structure of the rift, defined during the
initial stages of breakup, has played a dominant role in the initial development of magma assisted rifting in the MER. Surface structures and crustal-scale geophysical studies have suggested the WFB is analogous to a sea-floor spreading centre. However, the geochemical characteristics of rift basalts are consistent with mantle tomography that shows no evidence beneath the MER for passive magmatic upwelling beneath discrete rift segments as is observed in the ocean basins. Collectively, the Ethiopian data show that the distribution of mantle melts during the initiation of magma assisted rifting is fundamentally influenced by
lithospheric structures formed during earlier syn-rift stretching.
83-96
Rooney, Tyrone O.
c5c64eee-082a-4199-861d-c1d83b50a92c
Bastow, Ian D.
7a2698d0-d535-4462-a9a9-0e3293d2d667
Keir, Derek
5616f81f-bf1b-4678-a167-3160b5647c65
2011
Rooney, Tyrone O.
c5c64eee-082a-4199-861d-c1d83b50a92c
Bastow, Ian D.
7a2698d0-d535-4462-a9a9-0e3293d2d667
Keir, Derek
5616f81f-bf1b-4678-a167-3160b5647c65
Rooney, Tyrone O., Bastow, Ian D. and Keir, Derek
(2011)
Insights into extensional processes during magma assisted rifting: Evidence from aligned scoria cones.
Journal of Volcanology and Geothermal Research, 201 (1-4), .
(doi:10.1016/j.jvolgeores.2010.07.019).
Abstract
Mechanical and magmatic processes exert first-order control on the architecture and evolution of rifts. As a continental rift develops towards a new oceanic spreading centre, extension that is initially accommodated in a broad zone of faulting and ductile stretching must transition towards a narrow zone of focused magmatic intrusion. The Main Ethiopian Rift (MER), part of the East African Rift System, is an ideal location to study this transition because it captures rifting processes during continental breakup. In this contribution we synthesise geochemical data from scoria cones in the Wonji Fault Belt (WFB) and Silti-Debre Zeyit Fault Zone (SDFZ) in the MER to provide new constraints on the development of mantle melting columns and magmatic plumbing systems since the onset of rifting. We utilize the extensive geophysical and geochemical databases, collected in the Ethiopian Rift, to show that geochemical evidence of heterogeneity in the depth of the mantle melting column which produced Quaternary rift basalts correlates with lithospheric structure. When combined with existing observations of asymmetry across the rift in terms of depth of melting column and magmatic plumbing systems, it is evident that the mechanical structure of the rift, defined during the
initial stages of breakup, has played a dominant role in the initial development of magma assisted rifting in the MER. Surface structures and crustal-scale geophysical studies have suggested the WFB is analogous to a sea-floor spreading centre. However, the geochemical characteristics of rift basalts are consistent with mantle tomography that shows no evidence beneath the MER for passive magmatic upwelling beneath discrete rift segments as is observed in the ocean basins. Collectively, the Ethiopian data show that the distribution of mantle melts during the initiation of magma assisted rifting is fundamentally influenced by
lithospheric structures formed during earlier syn-rift stretching.
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Published date: 2011
Organisations:
Geology & Geophysics
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Local EPrints ID: 200795
URI: http://eprints.soton.ac.uk/id/eprint/200795
ISSN: 0377-0273
PURE UUID: cc047123-26a2-4eb0-a352-4c576b0d6209
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Date deposited: 24 Oct 2011 08:38
Last modified: 15 Mar 2024 03:38
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Author:
Tyrone O. Rooney
Author:
Ian D. Bastow
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