During the structural and sedimentological evolution of rifted continental margins in carbonate dominated settings, a characteristic stage is commonly reached when pelagic carbonate sedimentation occurs in association with complex fault block systems. An integrated study of the ammonite biostratigraphy and sedimentology of Jurassic pelagic rocks in the Umbria‐Marche Apennines (central Italy) and in the Sila Mountains (north‐east Calabria, southern Italy) has revealed three distinctive facies associations which can be related to specific structural and depositional settings. The condensed pelagic facies association is the constituent of condensed, usually discontinuous sequences, with numerous hiatal surfaces. The normal and resedimented pelagic facies association is typical of thicker sequences, comprising gravity flow and rockfall deposits. The composite pelagic facies association is one in which rockfall deposits are found associated with condensed sequences containing minor or no gravity flow deposits. Palaeotopographical highs are dominated by the condensed pelagic facies association and constitute the pelagic carbonate platform (PCP). Structurally, the PCP can be coincident with the top of a horst (or ‘central high’) block or the crestal area of a tilted block. In the latter case, the sediment surface of the PCP slopes gently (maximum of 1–3°) in this, the shallowest area of a pelagic carbonate ramp. PCPs can have erosional, bypass (rare) and depositional margins. Stepped margins also exist as subparallel rows of erosional and bypass margins. Trends from erosional to depositional margins are usually seen as a response to basin filling and burial of submarine tectonic escarpments by pelagic deposits in late synrift or early post‐rift times. This is apparent from ‘progradation’ of PCP facies deposits beyond the structural boundaries of the PCP. Palaeoenvironmental analysis in pelagic carbonate platform deposits of the Umbria‐Marche Apennines suggests that drowning of ancestral peritidal carbonate platforms in Pliensbachian time was followed first by a moderate deepening and then by shallowing in the Tithonian.
In the Central Apennines, a Tertiary-Present eastward-vergent fold and thrust belt, thrusting mainly occurred in-sequence, cutting across a Mesozoic to Early Neogene succession, deposited in rifted (Early Jurassic) to passive continental margin, to foredeep (late Miocene) conditions. However, the Simbruini Mts were characterized by the occurrence of regional out-of-sequence thrusts (the Vallepietra-Filettino-Monte Ortara thrust fault) and ofTertiary prethrusting normal faults, associated with the deposition of thick breccia deposits (Brecce della Renga, Tortonian-early Messinian). A direct link between these two features is here proposed. Evidence for a prethrusting normal faulting origin for the Brecce della Renga is amply discussed. Although evidence for subduction-related normal faulting is growing in the Apennines literature, nowhere in the region are known extensional systems so vast and their syn-tectonic deposits so thick as in the Simbruini area. We propose that the Simbruini prethrusting normal faults were subduction related, i.e., they developed in the foreland due to anomalous bending of the lithosphere subducting in Late Tertiary time under the Apennines in the Simbruini Mts area. The associated breccia deposits were subsequently deformed during the development of the Simbruini Mts thrust front. We speculate that the prethrusting normal faults allowed the penetration of fluids within the subducting crust and possibly also in the mantle, weakening this part of the subducting plate. As a consequence, the weaker plate was anomalously down-bent, leading to a subcritical state of the Apennines wedge. The regional scale out-of-sequence thrust faults developed in order to bring the Apennines wedge back to the critical state.
In the central Apennines, interacting siliciclastic and carbonate marine clastic wedges filled the foreland basin system during the late Miocene. Conjunction of collisional thrust tectonics and prethrusting normal faults generated a complex foredeep with intrabasinal structural highs that represented additional source areas to the basin. \ud
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Detrital modes of the late Miocene central Apennines orogenic system range in composition from intrabasinal carbonate to quartzofeldspatholithic and calclithite arenites. The external zone of the foredeep is characterized by hemipelagic deposits, called the Orbulina Marl. Their arenite beds are composed by intrabasinal carbonate, with dominant bioclasts and minor intraclasts, and glauconite derived from an active shallow-marine carbonate source. These hemipelagic deposits are partly coeval with and partly overlain by siliciclastic turbidites of the Frosinone and the Argilloso-Arenacea Formations, and they represent deposition within local foredeep depocenters. Siliciclastic turbidite sandstones are quartzofeldspatholithic, which documents provenances from metamorphic, plutonic, ophiolitic, and sedimentary rocks. Carbonate intrabasinal structural highs were the main source for carbonate breccias, intrabasinal arenites, and calclithites of the Brecce della Renga Formation, the deposits of which are locally interbedded with the coeval siliciclastic turbidite sandstones. \ud
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Evolution of late Miocene sandstone detrital modes reflected the changing nature of the central Apennines thrust belt through time and the complex architecture of the foreland basin system; it records the history of accretion, deformation of the foredeep, and progressive areal reduction of carbonate-producing areas along with the sedimentary and structural evolution of local intrabasinal highs
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