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Uplift at lithospheric swells-I: seismic and gravity constraints on the crust and uppermost mantle structure of the Cape Verde mid-plate swell

Uplift at lithospheric swells-I: seismic and gravity constraints on the crust and uppermost mantle structure of the Cape Verde mid-plate swell
Uplift at lithospheric swells-I: seismic and gravity constraints on the crust and uppermost mantle structure of the Cape Verde mid-plate swell
Wide-angle seismic data have been used to determine the velocity and density structure of the crust and uppermost mantle beneath the Cape Verdes mid-plate swell. Seismic modelling reveals a ‘standard’ oceanic crust, ?8 km in thickness, with no direct evidence for low-density bodies at the base of the crust. Gravity anomaly modelling within the constraints and resolution provided by the seismic model, does not preclude, however, a layer of crustal underplate up to 3 km thick beneath the swell crest. The modelling shows that while the seismically constrained crustal structure accounts for the short-wavelength free-air gravity anomaly, it fails to fully explain the long-wavelength anomaly. The main discrepancy is over the swell crest where the gravity anomaly, after correcting for crustal structure, is higher by about 30 mGal than it is over its flanks. The higher gravity can be explained if the top 100 km of the mantle beneath the swell crest is less dense than its surroundings by 30 kg m?3. The lack of evidence for low densities and velocities in the uppermost mantle, and high densities and velocities in the lower crust, suggests that neither a depleted swell root or crustal underplate are the origin of the observed shallower-than-predicted bathymetry and that, instead, the swell is most likely supported by dynamic uplift associated with an anomalously low density asthenospheric mantle.
Controlled source seismology, Intraplate processes, Oceanic hotspots and intraplate volcanism, Lithospheric flexure, Crustal structure
0956-540X
531-550
Wilson, D.J.
8dce2f55-d270-45ca-b890-ed32dc143790
Peirce, C.
fac39ccd-a15e-4233-8158-91d83d50e461
Watts, A.B.
6c5f361f-d238-4226-8312-c0eb48ccecc5
Grevemeyer, I.
d11d0d65-9c65-48d3-948d-0599a7350a1a
Krabbenhoeft, A.
8d68b7a4-c20a-43c5-ae35-a0ec13d9c455
Wilson, D.J.
8dce2f55-d270-45ca-b890-ed32dc143790
Peirce, C.
fac39ccd-a15e-4233-8158-91d83d50e461
Watts, A.B.
6c5f361f-d238-4226-8312-c0eb48ccecc5
Grevemeyer, I.
d11d0d65-9c65-48d3-948d-0599a7350a1a
Krabbenhoeft, A.
8d68b7a4-c20a-43c5-ae35-a0ec13d9c455

Wilson, D.J., Peirce, C., Watts, A.B., Grevemeyer, I. and Krabbenhoeft, A. (2010) Uplift at lithospheric swells-I: seismic and gravity constraints on the crust and uppermost mantle structure of the Cape Verde mid-plate swell. Geophysical Journal International, 182 (2), 531-550. (doi:10.1111/j.1365-246X.2010.04641.x).

Record type: Article

Abstract

Wide-angle seismic data have been used to determine the velocity and density structure of the crust and uppermost mantle beneath the Cape Verdes mid-plate swell. Seismic modelling reveals a ‘standard’ oceanic crust, ?8 km in thickness, with no direct evidence for low-density bodies at the base of the crust. Gravity anomaly modelling within the constraints and resolution provided by the seismic model, does not preclude, however, a layer of crustal underplate up to 3 km thick beneath the swell crest. The modelling shows that while the seismically constrained crustal structure accounts for the short-wavelength free-air gravity anomaly, it fails to fully explain the long-wavelength anomaly. The main discrepancy is over the swell crest where the gravity anomaly, after correcting for crustal structure, is higher by about 30 mGal than it is over its flanks. The higher gravity can be explained if the top 100 km of the mantle beneath the swell crest is less dense than its surroundings by 30 kg m?3. The lack of evidence for low densities and velocities in the uppermost mantle, and high densities and velocities in the lower crust, suggests that neither a depleted swell root or crustal underplate are the origin of the observed shallower-than-predicted bathymetry and that, instead, the swell is most likely supported by dynamic uplift associated with an anomalously low density asthenospheric mantle.

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More information

Published date: August 2010
Keywords: Controlled source seismology, Intraplate processes, Oceanic hotspots and intraplate volcanism, Lithospheric flexure, Crustal structure
Organisations: Geology & Geophysics

Identifiers

Local EPrints ID: 348161
URI: http://eprints.soton.ac.uk/id/eprint/348161
ISSN: 0956-540X
PURE UUID: 2939798f-ccb8-4de8-9ab1-0d9bb52bec5a

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Date deposited: 07 Feb 2013 11:47
Last modified: 14 Mar 2024 12:55

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Contributors

Author: D.J. Wilson
Author: C. Peirce
Author: A.B. Watts
Author: I. Grevemeyer
Author: A. Krabbenhoeft

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