What does it link the surface to the deep Earth’s processes? The tectonic evolution of the Congo basin: an example of intracratonic basin

Abstract: The origin of the intracratonic basins (ICBs) is still highly debated and several hypotheses have put forward to explain their long-lasting subsidence, characterized by prolonged intervals of low rate subsidence alternating with episodic accelerations in subsidence rate (e.g., Hartley &...

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Main Authors: Societa Geologica Italiana 2021, Tesauro, Magdala
Format: Article in Journal/Newspaper
Language:unknown
Published: Underline Science Inc. 2021
Subjects:
Geology
FOS Earth and related environmental sciences
Geomorphology
Seismology
Sedimentology
Climatology
Geodynamics
South Pole
South pole
Online Access:https://dx.doi.org/10.48448/nd74-e122
https://underline.io/lecture/33586-what-does-it-link-the-surface-to-the-deep-earth
id ftdatacite:10.48448/nd74-e122
record_format openpolar
spelling ftdatacite:10.48448/nd74-e122 2023-05-15T18:23:24+02:00 What does it link the surface to the deep Earth’s processes? The tectonic evolution of the Congo basin: an example of intracratonic basin Societa Geologica Italiana 2021 Tesauro, Magdala 2021 https://dx.doi.org/10.48448/nd74-e122 https://underline.io/lecture/33586-what-does-it-link-the-surface-to-the-deep-earth unknown Underline Science Inc. Geology FOS Earth and related environmental sciences Geomorphology Seismology Sedimentology Climatology Geodynamics Conference talk article Audiovisual MediaObject 2021 ftdatacite https://doi.org/10.48448/nd74-e122 2022-03-10T10:29:58Z Abstract: The origin of the intracratonic basins (ICBs) is still highly debated and several hypotheses have put forward to explain their long-lasting subsidence, characterized by prolonged intervals of low rate subsidence alternating with episodic accelerations in subsidence rate (e.g., Hartley & Allen, 1994). The Congo basin (CB) is a natural laboratory for investigating the processes that govern the long–term evolution of the ICBs, due to its long tectonic history, during which a large thickness of sediments deposited (up to about 9 km). Its subsidence initiated very probably as a failed rift in late Mesoproterozoic and evolved during the Neoproterozoic and Phanerozoic under the influence of far-field compressional tectonic events, global climate fluctuation between icehouse and greenhouse conditions and drifting of Central Africa through the South Pole then towards its present-day equatorial position (Delvaux et al., 2021). We reconstructed the depth of the basement and of main sedimentary layers of the CB, by integrating the interpretations of almost 3000 km of seismic reflection profiles with the analysis of the gravity field. The obtained results show a very heterogeneous basement depth, characterized by a series of topographic highs and lows NW-SE oriented (Delvaux et al., 2021; Maddaloni et al., 2021). We further observed the migration of the sedimentary depocenters from the Proterozoic to Jurassic times and lateral thickness variations of the sedimentary layers. Both types of observations reflect a different behavior of the CB during the stages of its evolution, with a progressive decrease in the influence of the initial rift structure. The rift phase that gave origin to the CB has been simulated applying multidirectional slow divergent velocities to a cratonic block having a central weak zone, representing the suture area between the cratonic pieces composing the Congo craton. The numerical models, after a time lapse of 200 Myr, show the formation of a central circular subsided area, as effect of the radial extension, induced by the asthenosphere upwelling. The main structures, formed within the depressed topographic area, resemble the present-day basement depth of the CB, supporting the hypothesis that the origin of some ICBs can be due to the effect of multi-extensional stress applied on a cratonic area. Authors:* Maddaloni F., Tesauro M.*, Delvaux D., Gerya T. & Braitenberg C. Article in Journal/Newspaper South pole DataCite Metadata Store (German National Library of Science and Technology) South Pole
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
topic Geology
FOS Earth and related environmental sciences
Geomorphology
Seismology
Sedimentology
Climatology
Geodynamics
spellingShingle Geology
FOS Earth and related environmental sciences
Geomorphology
Seismology
Sedimentology
Climatology
Geodynamics
Societa Geologica Italiana 2021
Tesauro, Magdala
What does it link the surface to the deep Earth’s processes? The tectonic evolution of the Congo basin: an example of intracratonic basin
topic_facet Geology
FOS Earth and related environmental sciences
Geomorphology
Seismology
Sedimentology
Climatology
Geodynamics
description Abstract: The origin of the intracratonic basins (ICBs) is still highly debated and several hypotheses have put forward to explain their long-lasting subsidence, characterized by prolonged intervals of low rate subsidence alternating with episodic accelerations in subsidence rate (e.g., Hartley & Allen, 1994). The Congo basin (CB) is a natural laboratory for investigating the processes that govern the long–term evolution of the ICBs, due to its long tectonic history, during which a large thickness of sediments deposited (up to about 9 km). Its subsidence initiated very probably as a failed rift in late Mesoproterozoic and evolved during the Neoproterozoic and Phanerozoic under the influence of far-field compressional tectonic events, global climate fluctuation between icehouse and greenhouse conditions and drifting of Central Africa through the South Pole then towards its present-day equatorial position (Delvaux et al., 2021). We reconstructed the depth of the basement and of main sedimentary layers of the CB, by integrating the interpretations of almost 3000 km of seismic reflection profiles with the analysis of the gravity field. The obtained results show a very heterogeneous basement depth, characterized by a series of topographic highs and lows NW-SE oriented (Delvaux et al., 2021; Maddaloni et al., 2021). We further observed the migration of the sedimentary depocenters from the Proterozoic to Jurassic times and lateral thickness variations of the sedimentary layers. Both types of observations reflect a different behavior of the CB during the stages of its evolution, with a progressive decrease in the influence of the initial rift structure. The rift phase that gave origin to the CB has been simulated applying multidirectional slow divergent velocities to a cratonic block having a central weak zone, representing the suture area between the cratonic pieces composing the Congo craton. The numerical models, after a time lapse of 200 Myr, show the formation of a central circular subsided area, as effect of the radial extension, induced by the asthenosphere upwelling. The main structures, formed within the depressed topographic area, resemble the present-day basement depth of the CB, supporting the hypothesis that the origin of some ICBs can be due to the effect of multi-extensional stress applied on a cratonic area. Authors:* Maddaloni F., Tesauro M.*, Delvaux D., Gerya T. & Braitenberg C.
format Article in Journal/Newspaper
author Societa Geologica Italiana 2021
Tesauro, Magdala
author_facet Societa Geologica Italiana 2021
Tesauro, Magdala
author_sort Societa Geologica Italiana 2021
title What does it link the surface to the deep Earth’s processes? The tectonic evolution of the Congo basin: an example of intracratonic basin
title_short What does it link the surface to the deep Earth’s processes? The tectonic evolution of the Congo basin: an example of intracratonic basin
title_full What does it link the surface to the deep Earth’s processes? The tectonic evolution of the Congo basin: an example of intracratonic basin
title_fullStr What does it link the surface to the deep Earth’s processes? The tectonic evolution of the Congo basin: an example of intracratonic basin
title_full_unstemmed What does it link the surface to the deep Earth’s processes? The tectonic evolution of the Congo basin: an example of intracratonic basin
title_sort what does it link the surface to the deep earth’s processes? the tectonic evolution of the congo basin: an example of intracratonic basin
publisher Underline Science Inc.
publishDate 2021
url https://dx.doi.org/10.48448/nd74-e122
https://underline.io/lecture/33586-what-does-it-link-the-surface-to-the-deep-earth
geographic South Pole
geographic_facet South Pole
genre South pole
genre_facet South pole
op_doi https://doi.org/10.48448/nd74-e122
_version_ 1766202986247225344

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