Long-lived, stationary magmatism and pulsed porphyry systems during Tethyan subduction to post-collision evolution in the southernmost Lesser Caucasus, Armenia and Nakhitchevan

Moritz, Robert; Rezeau, Hervé; Ovtcharova, Maria; Tayan, Rodrik; Melkonyan, Rafael; Hovakimyan, Samvel; Ramazanov, Vagif; Selby, David; Ulianov, Alexey; Chiaradia, Massimo; Putlitz, Benita

doi:10.1016/j.gr.2015.10.009

Cited by 101 publications

(37 citation statements)

References 148 publications

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“…14b). On the one hand, detailed petrological studies show that all these potassic rocks originated from mantle sources enriched by additional phases (see Castro et al, 2013;Kananian et al, 2014;Moritz et al, 2016;Ahmadian et al, 2016). As mentioned earlier, alkaline melt-mantle rock interaction could lead to the formation of phlogopite at lithospheric depths.…”

Section: Plutonic Rocksmentioning

confidence: 90%

“…Late Cretaceous to Eocene transitional high K calc-alkaline to potassic lavas and pyroclastic deposits (period 3) interlayered with sedimentary sequences follow the Lesser Caucasus, the Armenia block and the Talysh Mountains in the north-east border of NW Iran (Vincent et al, 2005). Eocene to Oligo-Miocene lavas and associated plutonic rocks (period 4) with high K calc-alkaline or potassic affinities only occur in Armenia and the NW of Iran (Aghazadeh et al, 2010;Castro et al, 2013;Moritz et al, 2016). Plio-Quaternary eruptions (younger than 3 Ma) are mainly exposed in the south of the Armenia block parallel to the Lesser Caucasus Suture and consist of medium to high K calc-alkaline mafic to intermediate lavas and pyroclastic deposits (e.g.…”

Section: The Lesser Caucasus-nw Iranmentioning

confidence: 99%

“…The plutonic rocks have been divided into Ferroan (A-type), potassic and infracrustal (I-type) high-K calc-alkaline granitoids (e.g. Dargahi et al, 2010;Karsli et al, 2012b;Castro et al, 2013;Nabatian et al, 2014;Kananian et al, 2014;Moritz et al, 2016;Ahmadian et al, 2016). The chemical characteristics of the granitoids are more complex than those of the volcanic rocks because their parental magmas experienced a variety of processes, including fractional crystallization (Karsli et al, 2012b;Castro et al, 2013;Nabatian et al, 2014;Kananian et al, 2014;Ahmadian et al, 2016).…”

Section: Plutonic Rocksmentioning

confidence: 99%

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Transport of Volatile-rich Melt from the Mantle Transition Zone via Compaction Pockets: Implications for Mantle Metasomatism and the Origin of Alkaline Lavas in the Turkish–Iranian Plateau

Soltanmohammadi

Grégoire

Rabinowicz

et al. 2018

Journal of Petrology

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Section: Plutonic Rocksmentioning

confidence: 90%

Section: The Lesser Caucasus-nw Iranmentioning

confidence: 99%

Section: Plutonic Rocksmentioning

confidence: 99%

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Transport of Volatile-rich Melt from the Mantle Transition Zone via Compaction Pockets: Implications for Mantle Metasomatism and the Origin of Alkaline Lavas in the Turkish–Iranian Plateau

Soltanmohammadi

Grégoire

Rabinowicz

et al. 2018

Journal of Petrology

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“…The Greater Caucasus basin opened as a back arc of the Lesser Caucasus Arc, to the north in present coordinates. Geochronologic and geochemical data from Jurassic to Eocene igneous rocks of the Lesser Caucasus indicate a subduction source [Mederer et al, 2013;Moritz et al, 2016;Sahakyan et al, 2016]. The modern structural architecture of active faults in the Lesser Caucasus is poorly understood, with north directed thrusting, south directed thrusting, and strike-slip faults all proposed as dominant structures [Koçyiğit et al, 2001;Philip et al, 1989;Rebaï et al, 1993].…”

Section: Lesser Caucasusmentioning

confidence: 99%

Relict basin closure and crustal shortening budgets during continental collision: An example from Caucasus sediment provenance

et al. 2016

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Comparison of plate convergence with the timing and magnitude of upper crustal shortening in collisional orogens indicates both shortening deficits (200–1700 km) and significant (10–40%) plate deceleration during collision, the cause(s) for which remains debated. The Greater Caucasus Mountains, which result from postcollisional Cenozoic closure of a relict Mesozoic back‐arc basin on the northern margin of the Arabia‐Eurasia collision zone, help reconcile these debates. Here we use U‐Pb detrital zircon provenance data and the regional geology of the Caucasus to investigate the width of the now‐consumed Mesozoic back‐arc basin and its closure history. The provenance data record distinct southern and northern provenance domains that persisted until at least the Miocene. Maximum basin width was likely ~350–400 km. We propose that closure of the back‐arc basin initiated at ~35 Ma, coincident with initial (soft) Arabia‐Eurasia collision along the Bitlis‐Zagros suture, eventually leading to ~5 Ma (hard) collision between the Lesser Caucasus arc and the Scythian platform to form the Greater Caucasus Mountains. Final basin closure triggered deceleration of plate convergence and tectonic reorganization throughout the collision. Postcollisional subduction of such small (102–103 km wide) relict ocean basins can account for both shortening deficits and delays in plate deceleration by accommodating convergence via subduction/underthrusting, although such shortening is easily missed if it occurs along structures hidden within flysch/slate belts. Relict basin closure is likely typical in continental collisions in which the colliding margins are either irregularly shaped or rimmed by extensive back‐arc basins and fringing arcs, such as those in the modern South Pacific.

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“…Arasbaran porphyry copper belt in the northwestern Iran bridges eastern and western parts of the Alp-Himalayan metallogenic belt. The belt stretches northwestward to Gharabagh Mountains in Azerbaijan which finally ends in Armenia and Turkey, hosting numerous porphyry copper deposits [5] [16]. The belt extends south and southeastward into Central Iran metallogenic belt.…”

Section: Regional and Ore Geologymentioning

confidence: 99%

Fluid Inclusion Studies on Quartz Veinlets at the Ali Javad Porphyry Copper (Gold) Deposit, Arasbaran, Northwestern Iran

Hajalilou¹,

Aghazadeh²

2016

GEP

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Ali Javad porphyry copper-gold deposit is located in Arasbaran porphyry copper belt at northwestern Iran, some 20 km east of Sungun Mine. Porphyry mineralization at the Ali Javad deposit occurred in post-Oligocene quartz monzonite bodies which intruded in the Eocene volcanic rocks. Mineralization occurred as veins, veinlets and dissemination both as hypogene and supergene type. Several types of veinlets were distinguished during the study of the deposit. Fluid inclusion studies on fluids trapped in quartz which were taken from drill core samples indicated a wide range of homogenization temperature in the veinlets from 138˚C to 565˚C which their salinity demonstrated 33-61 wt% NaCl equivalent. Mineralizing fluids density at the deposit was 0.8-1.2 g/cm 3. Fluid inclusion studies suggested that Ali Javad deposit is an Au-rich porphyry copper deposit; its fluid inclusion features were comparable with other porphyry deposits.

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Long-lived, stationary magmatism and pulsed porphyry systems during Tethyan subduction to post-collision evolution in the southernmost Lesser Caucasus, Armenia and Nakhitchevan

Cited by 101 publications

References 148 publications

Transport of Volatile-rich Melt from the Mantle Transition Zone via Compaction Pockets: Implications for Mantle Metasomatism and the Origin of Alkaline Lavas in the Turkish–Iranian Plateau

Transport of Volatile-rich Melt from the Mantle Transition Zone via Compaction Pockets: Implications for Mantle Metasomatism and the Origin of Alkaline Lavas in the Turkish–Iranian Plateau

Relict basin closure and crustal shortening budgets during continental collision: An example from Caucasus sediment provenance

Fluid Inclusion Studies on Quartz Veinlets at the Ali Javad Porphyry Copper (Gold) Deposit, Arasbaran, Northwestern Iran

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