Neo-Tethys geodynamics and mantle convection: from extension to compression in Africa and a conceptual model for obduction

Jolivet, Laurent; Faccenna, Claudio; Agard, Philippe; Lamotte, Dominique Frizon de; Menant, Armel; Sternai, Pietro; Guillocheau, François

doi:10.1139/cjes-2015-0118

Cited by 61 publications

(69 citation statements)

References 139 publications

(205 reference statements)

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“…This event is known everywhere in the northern part of Africa as the "Santonian Event" We st L ig u r ia n T e t h y s , 2005). It is also known in Europe (among others, Kley and Voigt, 2008;Jolivet et al, 2016; with references therein). Nonetheless, its effects remain weak or overprinted by subsequent events in the Tell-Rif.…”

Section: The First Tectonic Inversions Of the Southernmentioning

confidence: 99%

The Tell-Rif orogenic system (Morocco, Algeria, Tunisia) and the structural heritage of the southern Tethys margin

Leprêtre

Lamotte

Combier

et al. 2018

BSGF - Earth Sci. Bull.

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-The Tell-Rif (Tell in Algeria and Tunisia; Rif in Morocco) is the orogenic system fringing to the south the West Mediterranean basins. This system comprises three major tectonic-palaeogeographic zones from north to south: (1) the internal zones (AlKaPeCa for Alboran, Kabylies, Peloritan, Calabria) originating from the former northern European margin of the Maghrebian Tethys, (2) the "Flyschs zone" regarded as the former cover of the oceanic domain and (3) the external zones, forming the former southern Maghrebian Tethys margin more or less inverted. The Tell-Rif is interpreted as the direct result of the progressive closure of the Maghrebian Tethys until the collision between AlKaPeCa and Africa and, subsequently, the propagation of the deformation within Africa. This gives a consistent explanation for the offshore Neogene geodynamics and most authors share this simple scenario. Nevertheless, the current geodynamic models do not completely integrate the Tell-Rif geology. Based on the analysis of surface and sub-surface data, we propose a reappraisal of its present-day geometry in terms of geodynamic evolution. We highlight its non-cylindrical nature resulting from both the Mesozoic inheritance and the conditions of the tectonic inversion. During the Early Jurassic, we emphasize the development of NE-SW basins preceding the establishment of an E-W transform corridor connecting the Central Atlantic Ocean with the Ligurian Tethys. The Maghrebian Tethys developed just after, as the result of the Late Jurassic-Early Cretaceous left-lateral spreading between Africa and Iberia. By the Late Cretaceous, the occurrence of several tectonic events is related to the progressive convergence convergence between the two continents. A major pre-Oligocene (pre-35 Ma) compressional event is recorded in the Tell-Rif system. The existence of HP-LT metamorphic rocks associated with fragments of mantle in the External Metamorphic Massifs of the Eastern Rif and Western Tell shows that, at that time, the western part of the North-African margin was involved in a subduction below a deep basin belonging to the Maghrebian Tethys. At the same time, the closure of the West Ligurian Tethys through east-verging subduction led to a shift of the subduction, which jumped to the other side of AlKaPeCa involving both East Ligurian and Maghrebian Tethys. Slab rollback led to the development of the Oligo-Miocene back-arc basins of the West-Mediterranean, reworking the previous West Ligurian Tethys suture. The docking of AlKaPeCa against Africa occurred during the Late Burdigalian (17 Ma). Subsequently, the slab tearing triggered westward and eastward lateral movements that are responsible for the formation of the Gibraltar and Tyrrhenian Arcs respectively. The exhumation of the External Metamorphic Massifs occurred through tectonic underplating during the westward translation of the Alboran Domain. It resulted in the formation of both foredeep and wedge-top basins younger and younger westward. The lack of these elements in the eastern part ...

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Section: The First Tectonic Inversions Of the Southernmentioning

confidence: 99%

The Tell-Rif orogenic system (Morocco, Algeria, Tunisia) and the structural heritage of the southern Tethys margin

Leprêtre

Lamotte

Combier

et al. 2018

BSGF - Earth Sci. Bull.

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“…The main observation from these maps is that the extended and thin lithosphere of East and Southeast Asia lies over the leading edge of the southeastward lithospheric flow (Figures and ). This situation is reminiscent of the evolution of the African Plate since the Paleozoic with the rifting and detachment above the northward mantle flow of continental ribbons that then crossed the Tethys Ocean until they finally collided with the southern margin of Eurasia (Jolivet et al, ).…”

Section: Lithospheric Thicknessmentioning

confidence: 99%

“…Yet we know that different styles of convection may have significant consequences for the dynamics of mountain belts. For instance, whether slabs enter the lower mantle or not leads to orogens controlled by slab‐pull or slab suction and the transition between the two styles of subduction can lead to large‐scale obduction (Faccenna, Becker, Conrad, et al, ; Faccenna, Becker, Jolivet, et al, ; Husson et al, ; Jolivet et al, ). Although it was shown that the mantle flow induced by slab retreat is able to impose shearing conditions at the base of the overriding plate and controls deformation in the back‐arc region (Capitanio, ; Capitanio et al, ; Chen et al, ; Faccenna et al, ; Jolivet et al, ; Menant, Sternai, et al, ; Sternai et al, ), at larger scale, few tectonic models explain crustal deformation considering a possible drag by underlying currents (Conrad & Lithgow‐Bertelloni, ; Ghosh et al, ; Koptev et al, , ; Stoddard & Abbott, ).…”

Section: Introductionmentioning

confidence: 99%

Mantle Flow and Deforming Continents: From India‐Asia Convergence to Pacific Subduction

et al. 2018

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The formation of mountain belts or rift zones is commonly attributed to interactions between plates along their boundaries, but the widely distributed deformation of Asia from Himalaya to the Japan Sea and other back‐arc basins is difficult to reconcile with this notion. Through comparison of the tectonic and kinematic records of the last 50 Ma with seismic tomography and anisotropy models, we show that the closure of the former Tethys Ocean and the extensional deformation of East Asia can be best explained if the asthenospheric mantle transporting India northward, forming the Himalaya and the Tibetan Plateau, reaches East Asia where it overrides the westward flowing Pacific mantle and contributes to subduction dynamics, distributing extensional deformation over a 3,000‐km wide region. This deep asthenospheric flow partly controls the compressional stresses transmitted through the continent‐continent collision, driving crustal thickening below the Himalayas and Tibet and the propagation of strike‐slip faults across Asian lithosphere further north and east, as well as with the lithospheric and crustal flow powered by slab retreat east of the collision zone below East and SE Asia. The main shortening direction in the deforming continent between the collision zone and the Pacific subduction zones may in this case be a proxy for the direction of flow in the asthenosphere underneath, which may become a useful tool for studying mantle flow in the distant past. Our model of the India‐Asia collision emphasizes the role of asthenospheric flow underneath continents and may offer alternative ways of understanding tectonic processes.

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“…The push of the mantle plume impinged at the base of the African plate triggering local extension is shown to be sufficient for microblock separation. The presence of a continuous external push (possibly resulting from a large-scale mantle flow due to the large plume postulated by Jolivet et al, 2016) is shown to be indispensable to sustain continental subduction of the separated microblock (compare Figures 5a-5c and 5d). In contrast, variations in plume temperature do not appear to be crucial (models 2-3; Figures 3b and 3c).…”

Section: Discussionmentioning

confidence: 92%

Plume‐Induced Breakup of a Subducting Plate: Microcontinent Formation Without Cessation of the Subduction Process

Koptev

Beniest

Gerya

et al. 2019

Geophysical Research Letters

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Separation of microcontinents is explained by a ridge jump toward the passive margin as a possible consequence of plume‐induced rheological weakening, ultimately leading to breakup followed by accretion of the oceanic crust along a new spreading center. In contrast to such a purely extensional case, the separation of continental microblocks from the main body of the African plate during its continuous northward motion and subduction under Eurasia is still poorly understood. Our numerical experiments show the thermal and buoyancy effects of mantle plume impingement on the bottom of the continental part of a subducting plate are sufficient to induce separation of an isolated microcontinental block from the main subducting continent, even during induced plate motion necessary for uninterrupted oceanic and continental subduction. Subsequent continental accretion occurs by decoupling upper‐crustal nappes from the newly formed subducting microcontinent, which is in agreement with the Late Cretaceous‐Eocene evolution of the eastern Mediterranean.

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Neo-Tethys geodynamics and mantle convection: from extension to compression in Africa and a conceptual model for obduction

Cited by 61 publications

References 139 publications

The Tell-Rif orogenic system (Morocco, Algeria, Tunisia) and the structural heritage of the southern Tethys margin

The Tell-Rif orogenic system (Morocco, Algeria, Tunisia) and the structural heritage of the southern Tethys margin

Mantle Flow and Deforming Continents: From India‐Asia Convergence to Pacific Subduction

Plume‐Induced Breakup of a Subducting Plate: Microcontinent Formation Without Cessation of the Subduction Process

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