Aeromagnetic patterns in Southern Uruguay: Precambrian-Mesozoic dyke swarms and Mesozoic rifting structural and tectonic evolution

New high-resolution airborne magnetic data of Uruguay allowed constructing new maps concerning the spatial distribution of dyke swarms, main faults and other magnetic bodies, which compose the Uruguayan Shield. We combined geophysical analyses (vertical derivatives, upward continuation, Euler deconv...

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Veröffentlicht in:	Tectonophysics 2020-08, Vol.789, p.228373, Article 228373
Hauptverfasser:	Nuñez Demarco, Pablo, Masquelin, Henri, Prezzi, Claudia, Aïfa, Tahar, Muzio, Rossana, Loureiro, Judith, Peel, Elena, Campal, Nestor, Sánchez Bettucci, Leda
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Schlagworte:	Activation Aeromagnetic data Deformation Dyke swarm Earth Sciences Evolution Fault lines Geological data Geological faults Geological mapping Geological time Geophysics Magma Magnetic data Mesozoic Mesozoic Rift Orogeny Precambrian Rifting Rock intrusions Sciences of the Universe Shear Shear zone Shear zones Southern Uruguay Spatial distribution Structures Tectonics Transfer zone
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description	New high-resolution airborne magnetic data of Uruguay allowed constructing new maps concerning the spatial distribution of dyke swarms, main faults and other magnetic bodies, which compose the Uruguayan Shield. We combined geophysical analyses (vertical derivatives, upward continuation, Euler deconvolution), structural analyses of the magnetic maps and previous geological data in order to discriminate the main structural features of the Uruguayan Shield and contribute to a better understanding of its tectonic evolution. The magnetic maps revealed several outstanding features in the Uruguayan Shield. The Paleoproterozoic dyke swarm is larger, denser, more widespread and complex than originally thought, suggesting a possible plume origin. In addition, a new Mesozoic dyke swarm, as complex as the previous one, was identified crosscutting the Paleoproterozoic dyke swarm and the Neoproterozoic orogenic structures. Moreover, this swarm is connected to volcanic calderas in the Merín basin, and shows displacements along Neoproterozoic shear zones, in the magnetic maps, revealing its brittle reactivation during Mesozoic times. The new observations clarify how Proterozoic basement structures controlled the development of the Mesozoic rift. Paleoproterozoic dyke swarms were reactivated as normal faults and Neoproterozoic structures hindered the rift growth, deflecting the deformation in transcurrent movements. Meanwhile, the Mesozoic dyke swarm was developed in a perpendicular direction to the Neoproterozoic structures. Moreover, these findings contradict the current rift model for Uruguay and rise a new model in which the Mesozoic rift developed as two rift basins connected by a central transfer zone, generated by the reactivation of Dom Feliciano Belt structures, between the Sierra Ballena and Sarandí del Yí Shear Zones. •Several new dike swarms are identified in the Uruguayan basement using magnetic and structural criteria.•Paleoproterozoic Florida Dyke Swarm is better characterized and could indicate a mantle plume origin•Mesozoic Nico Pérez-Zapicán Dyke Swarm, is characterized and associated to volcanic calderas in the Merín rift basin.•A new Mesozoic Rift model is presented, where the central region, between Sear Zones, is described as a transfer zone.•Interrelationship between Gondwana dike swarms, Neoproterozoic structures and Mesozoic rifting are assessed.
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The new observations clarify how Proterozoic basement structures controlled the development of the Mesozoic rift. Paleoproterozoic dyke swarms were reactivated as normal faults and Neoproterozoic structures hindered the rift growth, deflecting the deformation in transcurrent movements. Meanwhile, the Mesozoic dyke swarm was developed in a perpendicular direction to the Neoproterozoic structures. 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We combined geophysical analyses (vertical derivatives, upward continuation, Euler deconvolution), structural analyses of the magnetic maps and previous geological data in order to discriminate the main structural features of the Uruguayan Shield and contribute to a better understanding of its tectonic evolution. The magnetic maps revealed several outstanding features in the Uruguayan Shield. The Paleoproterozoic dyke swarm is larger, denser, more widespread and complex than originally thought, suggesting a possible plume origin. In addition, a new Mesozoic dyke swarm, as complex as the previous one, was identified crosscutting the Paleoproterozoic dyke swarm and the Neoproterozoic orogenic structures. Moreover, this swarm is connected to volcanic calderas in the Merín basin, and shows displacements along Neoproterozoic shear zones, in the magnetic maps, revealing its brittle reactivation during Mesozoic times. The new observations clarify how Proterozoic basement structures controlled the development of the Mesozoic rift. Paleoproterozoic dyke swarms were reactivated as normal faults and Neoproterozoic structures hindered the rift growth, deflecting the deformation in transcurrent movements. Meanwhile, the Mesozoic dyke swarm was developed in a perpendicular direction to the Neoproterozoic structures. 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We combined geophysical analyses (vertical derivatives, upward continuation, Euler deconvolution), structural analyses of the magnetic maps and previous geological data in order to discriminate the main structural features of the Uruguayan Shield and contribute to a better understanding of its tectonic evolution. The magnetic maps revealed several outstanding features in the Uruguayan Shield. The Paleoproterozoic dyke swarm is larger, denser, more widespread and complex than originally thought, suggesting a possible plume origin. In addition, a new Mesozoic dyke swarm, as complex as the previous one, was identified crosscutting the Paleoproterozoic dyke swarm and the Neoproterozoic orogenic structures. Moreover, this swarm is connected to volcanic calderas in the Merín basin, and shows displacements along Neoproterozoic shear zones, in the magnetic maps, revealing its brittle reactivation during Mesozoic times. The new observations clarify how Proterozoic basement structures controlled the development of the Mesozoic rift. Paleoproterozoic dyke swarms were reactivated as normal faults and Neoproterozoic structures hindered the rift growth, deflecting the deformation in transcurrent movements. Meanwhile, the Mesozoic dyke swarm was developed in a perpendicular direction to the Neoproterozoic structures. Moreover, these findings contradict the current rift model for Uruguay and rise a new model in which the Mesozoic rift developed as two rift basins connected by a central transfer zone, generated by the reactivation of Dom Feliciano Belt structures, between the Sierra Ballena and Sarandí del Yí Shear Zones. •Several new dike swarms are identified in the Uruguayan basement using magnetic and structural criteria.•Paleoproterozoic Florida Dyke Swarm is better characterized and could indicate a mantle plume origin•Mesozoic Nico Pérez-Zapicán Dyke Swarm, is characterized and associated to volcanic calderas in the Merín rift basin.•A new Mesozoic Rift model is presented, where the central region, between Sear Zones, is described as a transfer zone.•Interrelationship between Gondwana dike swarms, Neoproterozoic structures and Mesozoic rifting are assessed.</abstract><cop>Amsterdam</cop><pub>Elsevier B.V</pub><doi>10.1016/j.tecto.2020.228373</doi><orcidid>https://orcid.org/0000-0003-4689-7880</orcidid><orcidid>https://orcid.org/0000-0001-7886-1271</orcidid><orcidid>https://orcid.org/0000-0001-6855-8447</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Activation Aeromagnetic data Deformation Dyke swarm Earth Sciences Evolution Fault lines Geological data Geological faults Geological mapping Geological time Geophysics Magma Magnetic data Mesozoic Mesozoic Rift Orogeny Precambrian Rifting Rock intrusions Sciences of the Universe Shear Shear zone Shear zones Southern Uruguay Spatial distribution Structures Tectonics Transfer zone
title	Aeromagnetic patterns in Southern Uruguay: Precambrian-Mesozoic dyke swarms and Mesozoic rifting structural and tectonic evolution
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