Reconciling plate motion and faulting at a rift-rift-rift triple junction
Reconciling plate motion and faulting at a rift-rift-rift triple junction
Rift-Rift-Rift triple junctions are regions where three plates interact, generating complex networks of variably oriented faults. While the geometry of the fault networks is easily constrained from their surface expression, what remains unclear is how the kinematics of faults and their interactions vary spatially, and how these relate to the unusual crustal motions that result from three plates diverging from each other. The Afar depression lies at the triple junction between the African, Arabian, and Somalian plates (in the Horn of Africa), where the unique combination of observational data from structural mapping, seismicity, and Global Navigation Satellite System (GNSS) allows us to understand the link between fault kinematics and plate motions. We complement these observations with an analog model to gain insights into how the patterns and directions of faults relate to overall plate motions. A key finding in both the model and nature is that some adjacent normal faults form at high angles and generate T-shaped structures. These purely normal faults are synchronously active, which means that the extension direction varies ~90° locally. These kinematic contrasts in our model and in nature occur despite the relatively smooth pattern of overall surface motions. The results indicate that normal faults interacting at high angles to form the T-shaped structures can evolve synchronously within a stress field that varies gently in magnitude but dramatically in orientation over a few kilometers.
362-366
Maestrelli, Daniele
1e8d2a80-0847-434e-8433-ed36c650e994
Sani, Federico
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Keir, Derek
5616f81f-bf1b-4678-a167-3160b5647c65
Pagli, Carolina
290edb22-712b-4563-a868-af4c21fdb6b0
La Rosa, Alessandro
3443c440-23fe-437e-b908-80f6b923c4ba
Muluneh, Ameha
9c48408f-650f-49ad-9133-bc201fa817ce
Brune, Sascha
2610fb89-af9e-4fae-8292-fac70ec15418
Corti, Giacomo
dce88b12-5b7a-43b1-8a58-5bd1bc13634c
23 February 2024
Maestrelli, Daniele
1e8d2a80-0847-434e-8433-ed36c650e994
Sani, Federico
6c59b4c4-ecca-4ecc-ba2c-66efa5e5e3df
Keir, Derek
5616f81f-bf1b-4678-a167-3160b5647c65
Pagli, Carolina
290edb22-712b-4563-a868-af4c21fdb6b0
La Rosa, Alessandro
3443c440-23fe-437e-b908-80f6b923c4ba
Muluneh, Ameha
9c48408f-650f-49ad-9133-bc201fa817ce
Brune, Sascha
2610fb89-af9e-4fae-8292-fac70ec15418
Corti, Giacomo
dce88b12-5b7a-43b1-8a58-5bd1bc13634c
Maestrelli, Daniele, Sani, Federico, Keir, Derek, Pagli, Carolina, La Rosa, Alessandro, Muluneh, Ameha, Brune, Sascha and Corti, Giacomo
(2024)
Reconciling plate motion and faulting at a rift-rift-rift triple junction.
Geology, 52 (5), .
(doi:10.1130/G51909.1).
Abstract
Rift-Rift-Rift triple junctions are regions where three plates interact, generating complex networks of variably oriented faults. While the geometry of the fault networks is easily constrained from their surface expression, what remains unclear is how the kinematics of faults and their interactions vary spatially, and how these relate to the unusual crustal motions that result from three plates diverging from each other. The Afar depression lies at the triple junction between the African, Arabian, and Somalian plates (in the Horn of Africa), where the unique combination of observational data from structural mapping, seismicity, and Global Navigation Satellite System (GNSS) allows us to understand the link between fault kinematics and plate motions. We complement these observations with an analog model to gain insights into how the patterns and directions of faults relate to overall plate motions. A key finding in both the model and nature is that some adjacent normal faults form at high angles and generate T-shaped structures. These purely normal faults are synchronously active, which means that the extension direction varies ~90° locally. These kinematic contrasts in our model and in nature occur despite the relatively smooth pattern of overall surface motions. The results indicate that normal faults interacting at high angles to form the T-shaped structures can evolve synchronously within a stress field that varies gently in magnitude but dramatically in orientation over a few kilometers.
Text
maestrelli_geology
- Accepted Manuscript
More information
Accepted/In Press date: 13 February 2024
Published date: 23 February 2024
Additional Information:
Publisher Copyright:
© (2024) Geological Society of America.
Identifiers
Local EPrints ID: 490092
URI: http://eprints.soton.ac.uk/id/eprint/490092
ISSN: 0091-7613
PURE UUID: 65eb09bc-46ac-47e4-89a4-babd128c3795
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Date deposited: 14 May 2024 16:48
Last modified: 05 Jun 2024 01:44
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Contributors
Author:
Daniele Maestrelli
Author:
Federico Sani
Author:
Carolina Pagli
Author:
Alessandro La Rosa
Author:
Ameha Muluneh
Author:
Sascha Brune
Author:
Giacomo Corti
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