A Preliminary Framework for Magmatism in Modern Continental Back‐Arc Basins and Its Application to the Triassic‐Jurassic Tectonic Evolution of the Caucasus

Vasey, Dylan; Cowgill, Eric; Cooper, Kari M.

doi:10.1029/2020gc009490

Cited by 17 publications

(25 citation statements)

References 206 publications

(511 reference statements)

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“…This proposed distinct phase of Permian to Triassic deposition is consistent with the stratigraphy of the Northern Caucasus, where Tikhomirov et al (2004) described intensely folded Devonian to Carboniferous strata unconformably overlain by Triassic siliciclastic, carbonate and volcanic strata. The volcanic component of these Triassic rocks has been interpreted as originating in a Permian to Triassic continental‐margin arc that formed north of the present‐day Greater Caucasus above a north‐dipping (present orientation) subduction zone (Figures 2d and 7; Natal'in & Şengör, 2005;Okay & Nikishin, 2015 ; Vasey et al, 2021). We infer that Triassic deposition of samples SV2 and SV3 in the present‐day Greater Caucasus, south of this arc, took place in a forearc basin and interpret the Permian to Triassic strata identified in this study as a more distal part of this forearc basin, rather than an early phase of deposition in the back‐arc basin that subsequently opened in Jurassic time (Figure 7).…”

Section: Discussionmentioning

confidence: 99%

“…Gamkrelidze & Kakhazdze, 1959; Gudjabidze, 2003; Kandelaki & Kakhazdze, 1957; Potapenko, 1964) and thus provide insight into the major phase of back‐arc basin evolution in the Caucasus Basin (e.g. Cowgill et al, 2016; Vasey et al, 2021; Vincent et al, 2016; Zonenshain & Le Pichon, 1986).…”

Section: Discussionmentioning

confidence: 99%

“…By Permian to Early Triassic time, northward subduction had initiated along the Laurasian margin beneath the Greater Caucasus, leading to arc magmatism within the present‐day Scythian Platform and Northern Caucasus (Figure 2d; Alexandre et al, 2004; Gerasimov et al, 2015; Natal'in & Şengör, 2005; Okay & Nikishin, 2015; Tikhomirov et al, 2004; Vasey et al, 2021). The younger sedimentary cover of the Scythian Platform obfuscates the geological record of this phase, and only a few Triassic arc rocks have been directly dated in well cores from the Scythian Platform or outcrop samples in the Northern Caucasus (Alexandre et al, 2004; Gerasimov et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Episodic evolution of a protracted convergent margin revealed by detrital zircon geochronology in the Greater Caucasus

Vasey,

Garcia,

Cowgill

et al. 2023

Basin Research

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Convergent margins play a fundamental role in the construction and modification of Earth's lithosphere and are characterized by poorly understood episodic processes that occur during the progression from subduction to terminal collision. On the northern margin of the active Arabia‐Eurasia collision zone, the Greater Caucasus Mountains provide an opportunity to study a protracted convergent margin that spanned most of the Phanerozoic and culminated in Cenozoic continental collision. However, the main episodes of lithosphere formation and deformation along this margin remain enigmatic. Here, we use detrital zircon U–Pb geochronology from Paleozoic and Mesozoic (meta)sedimentary rocks in the Greater Caucasus, along with select zircon U–Pb and Hf isotopic data from coeval igneous rocks, to link key magmatic and depositional episodes along the Caucasus convergent margin. Devonian to Early Carboniferous rocks were deposited prior to Late Carboniferous accretion of the Greater Caucasus crystalline core onto the Laurussian margin. Permian to Triassic rocks document a period of northward subduction and forearc deposition south of a continental margin volcanic arc in the Northern Caucasus and Scythian Platform. Jurassic rocks record the opening of the Caucasus Basin as a back‐arc rift during southward migration of the arc front into the Lesser Caucasus. Cretaceous rocks have few Jurassic‐Cretaceous zircons, indicating a period of relative magmatic quiescence and minimal exhumation within this basin. Late Cenozoic closure of the Caucasus Basin juxtaposed the Lesser Caucasus arc to the south against the crystalline core of the Greater Caucasus to the north and led to the formation of a hypothesized terminal suture. We expect this suture to be within ~20 km of the southern range front of the Greater Caucasus because all analysed rocks to the north exhibit a provenance affinity with the crystalline core of the Greater Caucasus.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Episodic evolution of a protracted convergent margin revealed by detrital zircon geochronology in the Greater Caucasus

Vasey,

Garcia,

Cowgill

et al. 2023

Basin Research

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“…The Caucasus region has a complex tectonic history, with multiple episodes of subduction, terrane accretion, and rifting during Phanerozoic time (Adamia et al., 2011; Şengör, 1984; Stampfli, 2013; Vasey et al., 2020). The successions of marine sedimentary rocks and volcaniclastic rocks exposed across the majority of the orogen record Jurassic to Eocene deposition in a backarc basin, termed the Greater Caucasus Basin, on the Eurasian margin north of the Jurassic to Eocene Lesser Caucasus magmatic arc (Figure 2; Cowgill et al., 2016; Nalivkin, 1976; Tye et al., 2021; Vasey et al., 2021; Vincent et al., 2016; Zonenshain & Pichon, 1986). The Greater Caucasus Basin was subsequently closed during the Cenozoic Arabia‐Eurasia collision (Adamia et al., 2011; Cowgill et al., 2016; Khain, 1975; Vincent et al., 2007).…”

Section: Geological Backgroundmentioning

confidence: 99%

Diverse Deformation Mechanisms and Lithologic Controls in an Active Orogenic Wedge: Structural Geology and Thermochronometry of the Eastern Greater Caucasus

Cowgill

et al. 2022

Tectonics

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Orogenic wedges are common at convergent plate margins and deform internally to maintain a self‐similar geometry during growth. New structural mapping and thermochronometry data illustrate that the eastern Greater Caucasus mountain range of western Asia undergoes deformation via distinct mechanisms that correspond with contrasting lithologies of two sedimentary rock packages within the orogen. The orogen interior comprises a package of Mesozoic thin‐bedded (<10 cm) sandstones and shales. These strata are deformed throughout by short‐wavelength (<1 km) folds that are not fault‐bend or fault‐propagation folds. In contrast, a coeval package of thick‐bedded (up to 5 m) volcaniclastic sandstone and carbonate, known as the Vandam Zone, has been accreted and is deformed via imbrication of coherent thrust sheets forming fault‐related folds of 5–10 km wavelength. Structural reconstructions and thermochronometric data indicate that the Vandam Zone package was accreted between ca. 13 and 3 Ma. Following Vandam Zone accretion, thermal modeling of thermochronometric data indicates rapid exhumation (∼0.3–1 mm/yr) in the wedge interior beginning between ca. 6 and 3 Ma, and a novel thermochronometric paleo‐rotation analysis suggests out‐of‐sequence folding of wedge‐interior strata after ca. 3 Ma. Field relationships suggest that the Vandam Zone underwent syn‐convergent extension following accretion. Together, the data record spatially and temporally variable deformation, dependent on both the mechanical properties of deforming lithologies and perturbations such as accretion of material from the down‐going to the overriding plate. The diverse modes of deformation are consistent with the maintenance of critical taper.

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“…1). The Tyrrhenian represents an example of the seafloor spreading stage in a continental back-arc setting 4 , formed following continental crust rifting behind the Aeolian Volcanic Arc and Calabrian suture zone during subduction and retreat of the Ionian plate 5 . Magmatic activity of the MV took place in the last 0.7 million years, producing primarily basaltic and basaltic andesite lavas; volumetrically minor andesite lavas were recovered at the summit cone of the volcano 6 (Fig.…”

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confidence: 99%

Crystals Detail Magma Production and Crust Formation at an Active Back-Arc Submarine Volcano

Trua¹,

Marani²,

Gamberi³

2021

Preprint

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Magmatic reservoirs feed active volcanoes and contribute to Earth’s crust formation. Among the processes operating in these systems, those controlling the early chemical evolution stages of magma are the most difficult to identify. This paper reports the first multi-mineral crystal archive that offers insights on the magmatic dynamics governing the production of basalt to andesite lavas at an oceanic back-arc spreading centre. As a result of these dynamics, a mush-dominated transcrustal system developed in the last 0.7 million years. The micro-scale crystal view identifies physicochemical magmatic environments that pass unobserved using whole-rock chemistry alone. It also supplies an interpretative formation model for plumbing system components, functional for the interpretation of geophysical data.

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A Preliminary Framework for Magmatism in Modern Continental Back‐Arc Basins and Its Application to the Triassic‐Jurassic Tectonic Evolution of the Caucasus

Cited by 17 publications

References 206 publications

Episodic evolution of a protracted convergent margin revealed by detrital zircon geochronology in the Greater Caucasus

Episodic evolution of a protracted convergent margin revealed by detrital zircon geochronology in the Greater Caucasus

Diverse Deformation Mechanisms and Lithologic Controls in an Active Orogenic Wedge: Structural Geology and Thermochronometry of the Eastern Greater Caucasus

Crystals Detail Magma Production and Crust Formation at an Active Back-Arc Submarine Volcano

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