Coevolution of craton margins and interiors during continental breakup
Coevolution of craton margins and interiors during continental breakup
Many cratonic continental fragments dispersed during the rifting and break-up of Gondwana are bound by steep topographic landforms known as ‘great escarpments’1,2,3,4, which rim elevated plateaus in the craton interior5,6. In terms of formation, escarpments and plateaus are traditionally considered distinct owing to their spatial separation, occasionally spanning more than a thousand kilometres. Here we integrate geological observations, statistical analysis, geodynamic simulations and landscape-evolution models to develop a physical model that mechanistically links both phenomena to continental rifting. Escarpments primarily initiate at rift-border faults and slowly retreat at about 1 km Myr−1 through headward erosion. Simultaneously, rifting generates convective instabilities in the mantle7,8,9,10 that migrate cratonward at a faster rate of about 15–20 km Myr−1 along the lithospheric root, progressively removing cratonic keels11, driving isostatic uplift of craton interiors and forming a stable, elevated plateau. This process forces a synchronized wave of denudation, documented in thermochronology studies, which persists for tens of millions of years and migrates across the craton at a comparable or slower pace. We interpret the observed sequence of rifting, escarpment formation and exhumation of craton interiors as an evolving record of geodynamic mantle processes tied to continental break-up, upending the prevailing notion of cratons as geologically stable terrains.
327–335
Gernon, Thomas M.
658041a0-fdd1-4516-85f4-98895a39235e
Hincks, Thea K.
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Brune, Sascha
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Braun, Jean
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Jones, Stephen M.
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Keir, Derek
5616f81f-bf1b-4678-a167-3160b5647c65
Cunningham, Alice
6119aaa8-ff69-44f7-92c5-c1f4dda1ce03
Glerum, Anne
2d1c3860-a716-4f76-a743-8ed8d91b1151
8 August 2024
Gernon, Thomas M.
658041a0-fdd1-4516-85f4-98895a39235e
Hincks, Thea K.
9654038a-2f5c-40bc-8f0e-33afc0b1fb71
Brune, Sascha
71db18c3-ae5a-4462-8bcd-37320ad6a9b5
Braun, Jean
acc81e8a-768e-4e90-8be1-c5964c9561d5
Jones, Stephen M.
87ce2106-3729-4775-9538-38beec21a0fe
Keir, Derek
5616f81f-bf1b-4678-a167-3160b5647c65
Cunningham, Alice
6119aaa8-ff69-44f7-92c5-c1f4dda1ce03
Glerum, Anne
2d1c3860-a716-4f76-a743-8ed8d91b1151
Gernon, Thomas M., Hincks, Thea K., Brune, Sascha, Braun, Jean, Jones, Stephen M., Keir, Derek, Cunningham, Alice and Glerum, Anne
(2024)
Coevolution of craton margins and interiors during continental breakup.
Nature, 632 (8024), .
(doi:10.1038/s41586-024-07717-1).
Abstract
Many cratonic continental fragments dispersed during the rifting and break-up of Gondwana are bound by steep topographic landforms known as ‘great escarpments’1,2,3,4, which rim elevated plateaus in the craton interior5,6. In terms of formation, escarpments and plateaus are traditionally considered distinct owing to their spatial separation, occasionally spanning more than a thousand kilometres. Here we integrate geological observations, statistical analysis, geodynamic simulations and landscape-evolution models to develop a physical model that mechanistically links both phenomena to continental rifting. Escarpments primarily initiate at rift-border faults and slowly retreat at about 1 km Myr−1 through headward erosion. Simultaneously, rifting generates convective instabilities in the mantle7,8,9,10 that migrate cratonward at a faster rate of about 15–20 km Myr−1 along the lithospheric root, progressively removing cratonic keels11, driving isostatic uplift of craton interiors and forming a stable, elevated plateau. This process forces a synchronized wave of denudation, documented in thermochronology studies, which persists for tens of millions of years and migrates across the craton at a comparable or slower pace. We interpret the observed sequence of rifting, escarpment formation and exhumation of craton interiors as an evolving record of geodynamic mantle processes tied to continental break-up, upending the prevailing notion of cratons as geologically stable terrains.
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Gernonetal2024
- Accepted Manuscript
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s41586-024-07717-1
- Version of Record
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Accepted/In Press date: 13 June 2024
e-pub ahead of print date: 7 August 2024
Published date: 8 August 2024
Identifiers
Local EPrints ID: 492775
URI: http://eprints.soton.ac.uk/id/eprint/492775
ISSN: 0028-0836
PURE UUID: dac11d6f-d772-42cd-ad49-075ec0091322
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Date deposited: 13 Aug 2024 17:04
Last modified: 28 Aug 2024 04:01
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Contributors
Author:
Thea K. Hincks
Author:
Sascha Brune
Author:
Jean Braun
Author:
Stephen M. Jones
Author:
Alice Cunningham
Author:
Anne Glerum
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