Influence of Peruvian flat-subduction dynamics on the evolution of western Amazonia
Influence of Peruvian flat-subduction dynamics on the evolution of western Amazonia
Convection in the Earth's mantle is mainly driven by cold, dense subducting slabs, but relatively little is known about how 3D variations in slab morphology and buoyancy affect mantle flow or how the surface above deforms in response (i.e. dynamic topography). We investigate this problem by studying the dynamics of an active region of flat-slab subduction located in Peru in South America. Here the slab geometry is well known, based on the regional seismicity, and we have observations from the local geological record to validate our models. Of particular interest is the widespread subsidence and deposition of the Solimões Formation across western Amazonia that coincided with the development of the Peruvian flat-slab during the Mid-Late Miocene. This formation covers an extensive area from the foredeep to the Purus Arch located View the MathML source?2000km away from the trench. Close to the Andes the preservation of several kilometers of sedimentary thicknesses can be easily accounted for by flexure. Based on an estimate of the Andean loading we predict 2.8 to 3.6 km of accommodation space that spans 100 km. The spatial and temporal history of the Solimões Formation however, particularly the thick distal foreland accumulations up to 1.2 km deep, can only be matched with the addition of a longer-wavelength dynamic source of topography. Following the transition from normal to flat subduction, we predict over 1 km of dynamic subsidence (View the MathML source?1500km wide) that propagates over 1000 km away from the trench, tracking the subduction leading edge. This is followed by a pulse of dynamic uplift over the flat segment behind it. We therefore propose that a combination of uplift, flexure and dynamic topography during slab flattening in Peru is responsible for the sedimentation history and landscape evolution of western Amazonia that eventually led to the configuration of the Amazon Drainage Basin we know today.
dynamic topography, flat-slab subduction, Amazonia, Solimões Formation
250-260
Eakin, Caroline M.
767ea10a-757b-4db5-8705-0c79368f8606
Lithgow-Bertelloni, Carolina
821057e8-6a41-4714-af2c-ec3309c945db
Dávila, Federico M.
bfd95c1b-e274-482f-ab76-681e444acdca
15 October 2014
Eakin, Caroline M.
767ea10a-757b-4db5-8705-0c79368f8606
Lithgow-Bertelloni, Carolina
821057e8-6a41-4714-af2c-ec3309c945db
Dávila, Federico M.
bfd95c1b-e274-482f-ab76-681e444acdca
Eakin, Caroline M., Lithgow-Bertelloni, Carolina and Dávila, Federico M.
(2014)
Influence of Peruvian flat-subduction dynamics on the evolution of western Amazonia.
Earth and Planetary Science Letters, 404, .
(doi:10.1016/j.epsl.2014.07.027).
Abstract
Convection in the Earth's mantle is mainly driven by cold, dense subducting slabs, but relatively little is known about how 3D variations in slab morphology and buoyancy affect mantle flow or how the surface above deforms in response (i.e. dynamic topography). We investigate this problem by studying the dynamics of an active region of flat-slab subduction located in Peru in South America. Here the slab geometry is well known, based on the regional seismicity, and we have observations from the local geological record to validate our models. Of particular interest is the widespread subsidence and deposition of the Solimões Formation across western Amazonia that coincided with the development of the Peruvian flat-slab during the Mid-Late Miocene. This formation covers an extensive area from the foredeep to the Purus Arch located View the MathML source?2000km away from the trench. Close to the Andes the preservation of several kilometers of sedimentary thicknesses can be easily accounted for by flexure. Based on an estimate of the Andean loading we predict 2.8 to 3.6 km of accommodation space that spans 100 km. The spatial and temporal history of the Solimões Formation however, particularly the thick distal foreland accumulations up to 1.2 km deep, can only be matched with the addition of a longer-wavelength dynamic source of topography. Following the transition from normal to flat subduction, we predict over 1 km of dynamic subsidence (View the MathML source?1500km wide) that propagates over 1000 km away from the trench, tracking the subduction leading edge. This is followed by a pulse of dynamic uplift over the flat segment behind it. We therefore propose that a combination of uplift, flexure and dynamic topography during slab flattening in Peru is responsible for the sedimentation history and landscape evolution of western Amazonia that eventually led to the configuration of the Amazon Drainage Basin we know today.
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Published date: 15 October 2014
Keywords:
dynamic topography, flat-slab subduction, Amazonia, Solimões Formation
Organisations:
Geology & Geophysics
Identifiers
Local EPrints ID: 373312
URI: http://eprints.soton.ac.uk/id/eprint/373312
ISSN: 0012-821X
PURE UUID: d9c08296-b7f6-4501-b623-43d3a4bbe5f4
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Date deposited: 14 Jan 2015 13:40
Last modified: 14 Mar 2024 18:51
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Contributors
Author:
Caroline M. Eakin
Author:
Carolina Lithgow-Bertelloni
Author:
Federico M. Dávila
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