Core Complex Segmentation in North Aegean, A Dynamic View

Brun, Jean; Sokoutis, Dimitrios

doi:10.1029/2017tc004939

Cited by 31 publications

(24 citation statements)

References 97 publications

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“…Although the allochthons were originally stacked by thrusting, most of their present tectonic contacts are Eocene to Miocene extensional detachment faults (e.g. Brun & Sokoutis, 2018). Findings of microdiamond in metamorphic rocks established the RMC as an UHP metamorphic terrane (Collings et al., 2016; Mposkos & Kostopoulos, 2001; Perraki et al., 2006; Petrík et al., 2016; Schmidt et al., 2010).…”

Section: Introductionmentioning

confidence: 99%

Variscan ultra‐high‐pressure eclogite in the Upper Allochthon of the Rhodope Metamorphic Complex (Bulgaria)

et al. 2020

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The Rhodope Metamorphic Complex (RMC) in Bulgaria has been established as a Mesozoic ultra‐high‐pressure metamorphic province by findings of microdiamond in gneisses. Additionally, Variscan ultra‐high‐pressure metamorphism has been proposed for the Ograzhden/Vertiskos Unit in the Upper Allochthon of the RMC, based on findings of coesite, graphite pseudomorphs after diamond and indirect age constraints. We confirm ultra‐high‐pressure metamorphism of eclogites in this unit using thermobarometry, phase‐equilibrium modelling and the Variscan age of metamorphism using Lu–Hf garnet–whole‐rock dating. In Belica (southern Rila Mountains), kyanite‐ and phengite‐bearing eclogite enclosed in high‐grade gneisses records P‐T conditions of 3.0–3.5 GPa and 700–750°C. Lu–Hf dating of eclogite samples from Belica and Gega (Ograzhden Mountain), where coesite was found, yielded ages of 334.1 ± 1.8 and 334.0 ± 2.2 Ma, respectively, interpreted as the age of garnet growth during post‐collisional subduction of continental crust after closure of the Rheic Ocean.

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Section: Introductionmentioning

confidence: 99%

Variscan ultra‐high‐pressure eclogite in the Upper Allochthon of the Rhodope Metamorphic Complex (Bulgaria)

et al. 2020

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“…This causes the lithosphere-asthenosphere boundary (LAB) to move upwards and hot material to be advected to shallower depths. Rifts can generally be categorized into narrow and wide rifts: Narrow rifts consist of a pronounced rift valley less than 100 km wide, such as large parts of the East African Rift System [Ebinger and Scholz, 2012] or the Rhine graben [Brun et al, 1992], while wide rifts are characterized by several smaller horsts and grabens distributed over a larger area, as e.g., the Basin and Range Province or the Aegean [Hamilton, 1987;Rey et al, 2009;Brun and Sokoutis, 2018]. Numerical thermo-mechanical simulations show that narrow rifts form in strong crustal configurations, while deformation in wide rifts is less localized due to a weaker crustal rheology [Buck, 1991].…”

Section: Introductionmentioning

confidence: 99%

Is there a Speed Limit for the Thermal Steady-State Assumption in Continental Rifts?

Heckenbach

Brune

Glerum

et al. 2022

Preprint

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“…This causes the lithosphere‐asthenosphere boundary (LAB) to move upwards and hot material to be advected to shallower depths. Rifts can generally be categorized into narrow and wide rifts: Narrow rifts feature pronounced rift valleys less than 100 km wide, as in large parts of the East African Rift System (Ebinger & Scholz, 2012) or the Rhine graben (Brun et al., 1992), while wide rifts are characterized by several smaller horsts and grabens distributed over a larger area, as for example, the Basin and Range Province or the Aegean (Brun & Sokoutis, 2018; Hamilton, 1987; Rey et al., 2009). Numerical thermo‐mechanical simulations show that narrow rifts form in strong crustal configurations, while deformation in wide rifts is less localized due to a weaker crust and associated crust‐mantle decoupling (Buck, 1991).…”

Section: Introductionmentioning

confidence: 99%

Is There a Speed Limit for the Thermal Steady‐State Assumption in Continental Rifts?

Heckenbach

Brune

Glerum

et al. 2021

Geochem Geophys Geosyst

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The temperature distribution within the lithosphere exerts key control on major geological and geodynamic processes such as long-term tectonic deformation, seismicity, and geochemical reactions. To better understand the localization of deformation, for instance, one may describe the thermo-mechanical state of the lithosphere (Afonso & Ranalli, 2004; Burov, 2011) in order to numerically simulate forward tectonic deformation (e.g., Buck, 1991; Huismans et al., 2005). Additional to these fundamental processes, shallow crustal temperatures hold strong implications for applied research on the formation of georesources. For example, the depth of the 60°C and the 120°C isotherms are important indicators for a region's geothermal potential in terms of heat production and electricity, respectively (e.g., Gudmundsson, 1988), while the depth of the oil window (80°C-100°C) (e.g., Tissot et al., 1987) controls the sites of hydrocarbon formation. The thermal

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Core Complex Segmentation in North Aegean, A Dynamic View

Abstract: The core complexes of the North Aegean result from the gravity spreading of a thrust wedge, driven by the Hellenic slab rollback, since middle Eocene.

Cited by 31 publications

References 97 publications

Variscan ultra‐high‐pressure eclogite in the Upper Allochthon of the Rhodope Metamorphic Complex (Bulgaria)

Variscan ultra‐high‐pressure eclogite in the Upper Allochthon of the Rhodope Metamorphic Complex (Bulgaria)

Is there a Speed Limit for the Thermal Steady-State Assumption in Continental Rifts?

Is There a Speed Limit for the Thermal Steady‐State Assumption in Continental Rifts?

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