Change in tectonic force inferred from basin subsidence: Implications for the dynamical aspects of back-arc rifting in the western Mediterranean

Abstract In the western Mediterranean area, after a long period (late Paleogene-Neogene) of Nubian (W-Africa) northward subduction beneath Eurasia, subduction has almost ceased, as well as convergence accommodation in the subduction zone. With the progression of Nubia-Eurasia convergence, a tectonic reorganization is therefore necessary to accommodate future contraction. Previously-published tectonic, seismological, geodetic, tomographic, and seismic reflection data (integrated by some new GPS velocity data) are reviewed to understand the reorganization of the convergent boundary in the western Mediterranean. Between northern Morocco, to the west, and northern Sicily, to the east, contractional deformation has shifted from the former subduction zone to the margins of the two back-arc oceanic basins (Algerian-Liguro-Provençal and Tyrrhenian basins) and it is now mainly active in the south-Tyrrhenian (northern Sicily), northern Liguro-Provençal, Algerian, and Alboran (partly) margins. Onset of compression and basin inversion has propagated in a scissor-like manner from the Alboran (c. 8 Ma) to the Tyrrhenian (younger than c. 2 Ma) basins following a similar propagation of the cessation of the subduction, i.e., older to the west and younger to the east. It follows that basin inversion is rather advanced on the Algerian margin, where a new southward subduction seems to be in its very infant stage, while it has still to really start in the Tyrrhenian margin, where contraction has resumed at the rear of the fold-thrust belt and may soon invert the Marsili oceanic basin. Part of the contractional deformation may have shifted toward the north in the Liguro-Provençal basin possibly because of its weak rheological properties compared with those of the area between Tunisia and Sardinia, where no oceanic crust occurs and seismic deformation is absent or limited. The tectonic reorganization of the Nubia-Eurasia boundary in the study area is still strongly controlled by the inherited tectonic fabric and rheological attributes, which are strongly heterogeneous along the boundary. These features prevent, at present, the development of long and continuous thrust faults. In an extreme and approximate synthesis, the evolution of the western Mediterranean is inferred to follow a Wilson Cycle (at a small scale) with the following main steps : (1) northward Nubian subduction with Mediterranean back-arc extension (since ~35 Ma); (2) progressive cessation, from west to east, of Nubian main subduction (since ~15 Ma); (3) progressive onset of compression, from west to east, in the former back-arc domain and consequent basin inversion (since ~8–10 Ma); (4) possible future subduction of former back-arc basins.

Download Full-text

Tectonic evolution of the Sicilian Maghrebian Chain inferred from stratigraphic and petrographic evidences of Lower Cretaceous and Oligocene flysch

Geologica Carpathica ◽

10.2478/geoca-2014-0020 ◽

2014 ◽

Vol 65 (4) ◽

pp. 293-305 ◽

Cited By ~ 5

Author(s):

Diego Puglisi

Keyword(s):

Lower Cretaceous ◽

Western Mediterranean ◽

Geological Evidence ◽

The Balkans ◽

Early Oligocene ◽

Gulf Of Lion ◽

Tectonic Development ◽

Thinned Continental Crust ◽

Almost All ◽

Back Arc

Abstract The occurrence of a Lower Cretaceous flysch group, cropping out from the Gibraltar Arc to the Balkans with a very similar structural setting and sedimentary provenance always linked to the dismantling of internal areas, suggests the existence of only one sedimentary basin (Alpine Tethys s.s.), subdivided into many other minor oceanic areas. The Maghrebian Basin, mainly developed on thinned continental crust, was probably located in the westernmost sector of the Alpine Tethys. Cretaceous re-organization of the plates triggered one (or more) tectonic phases, well recorded in almost all the sectors of the Alpine Tethys. However, the Maghrebian Basin seems to have been deformed by Late- or post-Cretaceous tectonics, connected with a “meso-Alpine” phase (pre-Oligocene), already hypothesized since the beginning of the nineties. Field geological evidence and recent biostratigraphic data also support this important meso- Alpine tectonic phase in the Sicilian segment of the Maghrebian Chain, indicated by the deformations of a Lower Cretaceous flysch sealed by Lower Oligocene turbidite deposits. This tectonic development is emphasized here because it was probably connected with the onset of rifting in the southern paleomargin of the European plate, the detaching of the so-called AlKaPeCa block (Auct.; i.e. Alboran + Kabylian + Calabria and Peloritani terranes) and its fragmentation into several microplates. The subsequent early Oligocene drifting of these microplates led to the progressive closure of the Maghrebian Basin and the opening of new back-arc oceanic basins, strongly controlled by extensional processes, in the western Mediterranean (i.e. Gulf of Lion, Valencia Trough, Provençal Basin and Alboran Sea).

Download Full-text

Sedimentation and volcanism linked to multiphase rifting in an Oligo-Miocene intra-arc basin, Anglona, Sardinia

Geological Magazine ◽

10.1017/s0016756800004246 ◽

2000 ◽

Vol 137 (4) ◽

pp. 395-418 ◽

Cited By ~ 22

Author(s):

ALISON SOWERBUTTS

Keyword(s):

Sea Level ◽

Volcanic Rocks ◽

Western Mediterranean ◽

Second Phase ◽

Filling Material ◽

Calc Alkaline ◽

Accommodation Space ◽

Western Mediterranean Basin ◽

Half Graben ◽

Back Arc

Three extensional phases can be recognized in the northern, Anglona area of the Oligo-Miocene Sardinian Rift during a fifteen million year period which spanned Corsica–Sardinia continental microplate separation and Western Mediterranean back-arc basin opening. In response to this multiphase rifting, a complex facies architecture involving clastic, carbonate and volcanic rocks developed. Integrated onshore facies and structural analysis, dating and offshore seismic data are here used to reconstruct the tectono-stratigraphic history of the Anglona area. Initial late Oligocene extension created a half-graben geometry with syn-rift clastic deposits shed locally from fault-bounded highs, passing laterally to lacustrine marlstones. Calc-alkaline volcanic activity subsequently predominated as volcanic centres developed along one half-graben bounding fault. Voluminous pyroclastic and epiclastic material was supplied to the adjacent half-graben accommodation space and was deposited in marginal to marine conditions. Second-phase mid-Aquitanian–early Burdigalian extensional faulting, recognized from localized clastic syn-rift stratal wedges, truncated and subdivided the half-graben. The syn-rift sediments were sealed by a regionally correlated ignimbrite that in turn was offset by late second-phase faulting. Third-phase extensional fault movement which reactivated the original fault trend then occurred. A perched lake developed in the resultant topography coeval with the progressive marine transgression of lower areas. As sea-level rose during mid-Burdigalian times, reefal carbonates and grainstones developed on fault-block highs whilst calcarenites and marlstones were deposited in hangingwall locations. Initial extension was coeval with the formation of the Sardinian proto-rift and the initiation of the Western Mediterranean basin. Second-phase faulting occurred as the Corsica–Sardinia microplate rotated to its present position during Western Mediterranean back-arc basin spreading. Final extension can be correlated to a second major extension phase along the Oligo-Miocene Sardinian Rift following back-arc basin opening, as extension was transferred towards the fore-arc. In Anglona, the main influence of multiphase tectonism was on rift topography, providing accommodation space and localized uplifted source areas. Varying relative sea-level mainly controlled the broad types of facies belts that developed. Contemporaneous calc-alkaline volcanism played a major role in the supply of basin filling material and in changing the topography locally.

Download Full-text

Seismic imaging of Late Miocene (Messinian) evaporites from Western Mediterranean back-arc basins

Petroleum Geoscience ◽

10.1144/petgeo2015-096 ◽

2016 ◽

Vol 22 (4) ◽

pp. 297-308 ◽

Cited By ~ 13

Author(s):

M. Dal Cin ◽

A. Del Ben ◽

A. Mocnik ◽

F. Accaino ◽

R. Geletti ◽

...

Keyword(s):

Late Miocene ◽

Seismic Imaging ◽

Western Mediterranean ◽

Messinian Evaporites ◽

Back Arc

Download Full-text

Lithospheric boudinage in the Western Mediterranean back‐arc basin

Terra Nova ◽

10.1046/j.1365-3121.1997.d01-28.x ◽

1997 ◽

Vol 9 (4) ◽

pp. 184-187 ◽

Cited By ~ 100

Author(s):

E. Gueguen ◽

C. Doglioni ◽

M. Fernandez

Keyword(s):

Western Mediterranean ◽

Back Arc

Download Full-text

Evolution of Ordovician terranes in western Ireland and their possible Scottish equivalents

Transactions of the Royal Society of Edinburgh Earth Sciences ◽

10.1017/s0263593300005101 ◽

1990 ◽

Vol 81 (1) ◽

pp. 23-29 ◽

Cited By ~ 11

Author(s):

D. M. Williams

Keyword(s):

Shallow Water ◽

Deep Water ◽

Metamorphic Rocks ◽

The South ◽

Sediment Dispersal ◽

Early Ordovician ◽

Basin Subsidence ◽

Western Ireland ◽

Back Arc

ABSTRACTIn the W of Ireland the Ordovician rocks of South Mayo and Clew Bay are now juxtaposed but a comparison of the sedimentary histories of these two sequences shows that they accumulated in basins which were probably separated during most of their history. The large amount of terrigenous detritus present in the Arenig to Llanvirn elements of the South Mayo succession is not manifest in that of Clew Bay until the Llandeilo/Caradoc, by which time sedimentation in South Mayo had ceased. A comparison of the South Mayo Ordovician with that of Girvan in Scotland demonstrates that both sequences had a similar provenance. This source contained an ophiolite, granites and some (probably pre-Dalradian) metamorphic rocks. Sediment dispersal directions for the two sequences are opposite in sense, being primarily northward in South Mayo and southward at Girvan. The two stratigraphies indicate that basement subsidence behaviour in South Mayo was virtually the opposite of that at Girvan where initial shallow water sedimentation was rapidly succeeded by deep water environments at the end of the Llanvirn. The two basins may thus have been marginal to a single Ordovician arc complex. One reason for the opposite sense of basin subsidence may lie in the suggested reversal of subduction polarity during the Ordovician. In this scenario the South Mayo basin may be envisaged as lying to the N of a northward-facing arc during the early Ordovician. A new, northward, subduction direction instigated during the Llanvirn, resulted in a fore-arc basin at Girvan complemented by a closing back-arc basin in South Mayo.

Download Full-text

Models of Mediterranean back-arc basin formation

Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences ◽

10.1098/rsta.1981.0071 ◽

1981 ◽

Vol 300 (1454) ◽

pp. 383-402 ◽

Cited By ~ 21

Keyword(s):

Upper Mantle ◽

Structural Changes ◽

Pannonian Basin ◽

Quantitative Model ◽

Subsidence History ◽

Basin Subsidence ◽

Rear Part ◽

Basin Formation ◽

Back Arc ◽

Tyrrhenian Basin

During and mainly after the Tertiary continental collisions, regions of extension and subsidence developed within the Alpine-Mediterranean orogenic belt in the rear part of the contemporaneously active arcs. Mediterranean back-arc basins are characterized by a hot upper mantle, overlain by crust transitional from continental to oceanic, which reflects their different stages of maturation. The four basins considered here are, in order of increasing maturity, the Pannonian Basin, the Aegean Basin, the Alboransouth Balearic Basin and the Tyrrhenian Basin. Back-arc extension is not a rigid plate opening but rather an areal expansion associated with progressive bending of the arc. The most successful models suggested for the evolution of Mediterranean back-arc basins imply updoming of the asthenosphere accompanied by lithospheric attenuation, stretching and dyke intrusion. The force behind asthenospheric updoming is under debate; active and passive mechanisms have been suggested. It seems, however, certain that gravity plays an important role in initiating and maintaining back-arc extension. Basin subsidence is an isostatic response to structural changes of the lithosphere and to conductive decay of the associated heat anomaly. A quantitative model for basin formation can be obtained only if the subsidence history is well documented.

Download Full-text

Back-arc dynamics controlled by slab rollback and tearing: a reappraisal of seafloor spreading and kinematic evolution of the Eastern Algerian basin (western Mediterranean) in Middle-Late Miocene

10.1002/essoar.10506942.1 ◽

2021 ◽

Author(s):

Shaza Haidar ◽

Jacques Déverchère ◽

David Graindorge ◽

Mohamed Arab ◽

Mourad Medaouri ◽

...

Keyword(s):

Late Miocene ◽

Western Mediterranean ◽

Seafloor Spreading ◽

Kinematic Evolution ◽

Slab Rollback ◽

Back Arc

Download Full-text

Detailed tectonic reconstructions of the Western Mediterranean region for the last 35 Ma, insights on driving mechanisms

BSGF - Earth Sciences Bulletin ◽

10.1051/bsgf/2020040 ◽

2020 ◽

Vol 191 ◽

pp. 37

Author(s):

Adrien Romagny ◽

Laurent Jolivet ◽

Armel Menant ◽

Eloïse Bessière ◽

Agnès Maillard ◽

...

Keyword(s):

Subduction Zones ◽

Large Scale ◽

Complex Dynamics ◽

Numerical Models ◽

Western Mediterranean ◽

Northern Margin ◽

Driving Mechanisms ◽

Tectonic Reconstructions ◽

Mountain Belts ◽

Back Arc

Slab retreat, slab tearing and interactions of slabs are first-order drivers of the deformation of the overriding lithosphere. An independent description of the tectonic evolution of the back-arc and peripheral regions is a pre-requisite to test the proposed conceptual, analogue and numerical models of these complex dynamics in 3-D. We propose here a new series of detailed kinematics and tectonic reconstructions from 35 Ma to the Present shedding light on the driving mechanisms of back-arc rifting in the Mediterranean where several back-arc basins all started to form in the Oligocene. The step-by-step backward reconstructions lead to an initial situation 35 Ma ago with two subduction zones with opposite direction, below the AlKaPeCa block (i.e. belonging to the Alboran, Kabylies, Peloritani, Calabrian internal zones). Extension directions are quite variable and extension rates in these basins are high compared to the Africa-Eurasia convergence velocity. The highest rates are found in the Western Mediterranean, the Liguro-Provençal, Alboran and Tyrrhenian basins. These reconstructions are based on shortening rates in the peripheral mountain belts, extension rates in the basins, paleomagnetic rotations, pressure-temperature-time paths of metamorphic complexes within the internal zones of orogens, and kinematics of the large bounding plates. Results allow visualizing the interactions between the Alps, Apennines, Pyrenean-Cantabrian belt, Betic Cordillera and Rif, as well as back-arc basins. These back-arc basins formed at the emplacement of mountain belts with superimposed volcanic arcs, thus with thick, hot and weak crusts explaining the formation of metamorphic core complexes and the exhumation of large portions of lower crustal domains during rifting. They emphasize the role of transfer faults zones accommodating differential rates of retreat above slab tears and their relations with magmatism. Several transfer zones are identified, separating four different kinematic domains, the largest one being the Catalan-Balearic-Sicily Transfer Zone. Their integration in the wider Mediterranean realm and a comparison of motion paths calculated in several kinematic frameworks with mantle fabric shows that fast slab retreat was the main driver of back-arc extension in this region and that large-scale convection was a subsidiary driver for the pre-8 Ma period, though it became dominant afterward. Slab retreat and back-arc extension was mostly NW-SE until ∼ 20 Ma and the docking of the AlKaPeCa continental blocks along the northern margin of Africa induced a slab detachment that propagated eastward and westward, thus inducing a change in the direction of extension from NW-SE to E-W. Fast slab retreat between 32 and 8 Ma and induced asthenospheric flow have prevented the transmission of the horizontal compression due to Africa-Eurasia convergence from Africa to Eurasia and favored instead upper-plate extension driven by slab retreat. Once slab retreat had slowed down in the Late Miocene, this N-S compression was felt and recorded again from the High Atlas to the Paris Basin.

Download Full-text