Petrochronology and hygrochronology of tectono-metamorphic events

Bosse, Valérie; Villa, Igor M.

doi:10.1016/j.gr.2018.12.014

Cited by 53 publications

(28 citation statements)

References 86 publications

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“…To obtain time constraints on the evolution of the studied sector, monazite geochronology was performed [84,85]. Grain locations, internal features (inclusions, fractures, etc.)…”

Section: Methods and Analytical Techniquesmentioning

confidence: 99%

Kinematics and Timing Constraints in a Transpressive Tectonic Regime: The Example of the Posada-Asinara Shear Zone (NE Sardinia, Italy)

et al. 2020

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Detailed geological field mapping, integrated with meso- and microstructural investigations, kinematic of the flow and finite strain analyses, combined with geochronology, are fundamental tools to obtain information on the temperature–deformation–timing path of crystalline rocks and shear zone. The Posada-Asinara shear zone (PASZ) in northern Sardinia (Italy) is a steeply dipping km-thick transpressive shear zone. In the study area, located in the Baronie region (NE Sardinia), the presence of mylonites within the PASZ, affecting high- and medium-grade metamorphic rocks, provides an opportunity to quantify finite strain and kinematic vorticity. The main structures of the study area are controlled by a D2 deformation phase, linked to the PASZ activity, in which the strain is partitioned into folds and shear zone domains. Applying two independent vorticity methods, we detected an important variation in the percentage of pure shear and simple shear along the deformation gradient, that increases from south to north. We constrained, for the first time in this sector, the timing of the transpressive deformation by U–(Th)–Pb analysis on monazite. Results indicate that the shear zone has been active at ~325–300 Ma in a transpressive setting, in agreement with the ages of the other dextral transpressive shear zones in the southern Variscan belt.

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“…To obtain time constraints on the evolution of the studied sector, monazite geochronology was performed [84,85]. Grain locations, internal features (inclusions, fractures, etc.)…”

Section: Methods and Analytical Techniquesmentioning

confidence: 99%

Kinematics and Timing Constraints in a Transpressive Tectonic Regime: The Example of the Posada-Asinara Shear Zone (NE Sardinia, Italy)

et al. 2020

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“…In this sense, combined in situ petrologic and microstructural data allow to link deformation mechanisms, metamorphic reactions, and macroscopic structural features and to infer the relative timing of different mineral associations and microstructures (Goncalves et al, 2012;Hobbs et al, 2011;Johnson, 1999;Marsh et al, 2009;Oriolo et al, 2018;Skrzypek et al, 2011;Yakymchuk & Godin, 2012). The absolute timing of deformation and metamorphism, in turn, can be constrained by interpreting in situ geochronologic data in the light of microstructures, which provide insights into mineral equilibria, deformation mechanisms, and metamorphic reactions (Bosse & Villa, 2019;Gasser et al, 2015;Mulch & Cosca, 2004;Oriolo, et al, 2016;Oriolo et al, 2018;Schulz, 2017;Tchato et al, 2009;Villa et al, 2014;Williams & Jercinovic, 2012). Furthermore, the integration of structural, microstructural, petrologic, and geochronologic data permits reconstructing the crustal architecture of orogens and contributes on the understanding of their tectonic and geodynamic evolution (e.g., Endo & Wallis, 2017;Goscombe & Gray, 2009;Raimondo et al, 2010).…”

Section: 1029/2018tc005358mentioning

confidence: 99%

The Late Paleozoic Tectonometamorphic Evolution of Patagonia Revisited: Insights From the Pressure‐Temperature‐Deformation‐Time (P‐T‐D‐t) Path of the Gondwanide Basement of the North Patagonian Cordillera (Argentina)

et al. 2019

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Combined field structural analysis with in situ electron probe microanalysis Th‐U‐Pb monazite dating, petrologic, and microstructural data provides a reconstruction of the pressure‐temperature‐deformation‐time (P‐T‐D‐t) path of the Gondwanide basement of the North Patagonian Cordillera. For samples from the Challhuaco hill, the timing of development of the metamorphic S2 foliation and associated L2 lineation and tight to isoclinal F2 folds is constrained by monazite ages of 299 ± 8 and 302 ± 16 Ma during peak metamorphic conditions of ~ 650 °C and 11 kbar, achieved during prograde metamorphism and progressive deformation. Metamorphism and deformation of metamorphic complexes of the North Patagonian Andes seem to record Late Paleozoic crustal thickening and are coeval with metamorphism of accretionary complexes exposed further west in Chile, suggesting a coupled Late Devonian‐Carboniferous evolution. Instead of the result of continental collision, the Gondwanide orogeny might thus be essentially linked to transpression due to advancing subduction along the proto‐Pacific margin of Gondwana. On the other hand, second generation of monazite ages of 171 ± 9 and 170 ± 7 Ma constrains the timing of low‐grade metamorphism related to kink band and F3 open fold development during Jurassic transtension and emplacement of granitoids. Finally, a Cretaceous overprint, likely resulting from hydrothermal processes, is recorded by monazite ages of 110 ± 10 and 80 ± 20 Ma, which might be coeval with deformation along low‐grade shear zones during the onset of Andean transpression.

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“…This contrasts with the Eocene high‐pressure metamorphic rocks in the Lower Unit, dated by 40 Ar‐ 39 Ar on Tinos (Bröker et al, ) and indirectly by correlative rocks on other islands at ~52–45 Ma by U–Pb zircon (Tomaschek et al, ) and Lu–Hf in garnet (Dragovic et al, , ; Lagos et al, ). However, there are inherent problems in determining what part of the rock's complex history is actually being dated with the K–Ar, 40 Ar– 39 Ar, and Rb–Sr methods (e.g., Kelley, ; MacDonald et al, ; Bosse & Villa, ). Here we present new U–Pb zircon dates for the timing of formation and emplacement of the Tsiknias Ophiolite within the Upper Unit.…”

Section: Geology Of Tinosmentioning

confidence: 99%

The Age, Origin, and Emplacement of the Tsiknias Ophiolite, Tinos, Greece

et al. 2020

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The Tsiknias Ophiolite, exposed at the highest structural levels of Tinos, Greece, represents a thrust sheet of Tethyan oceanic crust and upper mantle emplaced onto the Attic‐Cycladic Massif. We present new field observations and a new geological map of Tinos, integrated with petrology, THERMOCALC phase diagram modeling, U–Pb geochronology and whole rock geochemistry, resulting in a tectonothermal model that describes the formation and emplacement of the Tsiknias Ophiolite and newly identified underlying metamorphic sole. The ophiolite comprises a succession of partially dismembered and structurally repeated ultramafic and gabbroic rocks that represent the Moho Transition Zone. A plagiogranite dated by U‐Pb zircon at 161.9 ± 2.8 Ma, reveals that the Tsiknias Ophiolite formed in a suprasubduction zone setting, comparable to the “East‐Vardar Ophiolites,” and was intruded by gabbros at 144.4 ± 5.6 Ma. Strongly sheared metamorphic sole rocks show a condensed and inverted metamorphic gradient, from partially anatectic amphibolites at P‐T conditions of ~8.5 kbar 850–600 °C, downstructural section to greenschist‐facies oceanic metasediments over ~250 m. Leucosomes generated by partial melting of the uppermost sole amphibolite, yielded a U‐Pb zircon protolith age of ~190 Ma and a high‐grade metamorphic‐anatectic age of 74.0 ± 3.5 Ma associated with ophiolite emplacement. The Tsiknias Ophiolite was therefore obducted ~90 Myr after it formed during initiation of a NE dipping intraoceanic subduction zone to the northeast of the Cyclades that coincides with Africa's plate motion changing from transcurrent to convergent. Continued subduction resulted in high‐pressure metamorphism of the Cycladic continental margin ~25 Myr later.

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Petrochronology and hygrochronology of tectono-metamorphic events

Cited by 53 publications

References 86 publications

Kinematics and Timing Constraints in a Transpressive Tectonic Regime: The Example of the Posada-Asinara Shear Zone (NE Sardinia, Italy)

Kinematics and Timing Constraints in a Transpressive Tectonic Regime: The Example of the Posada-Asinara Shear Zone (NE Sardinia, Italy)

The Late Paleozoic Tectonometamorphic Evolution of Patagonia Revisited: Insights From the Pressure‐Temperature‐Deformation‐Time (P‐T‐D‐t) Path of the Gondwanide Basement of the North Patagonian Cordillera (Argentina)

The Age, Origin, and Emplacement of the Tsiknias Ophiolite, Tinos, Greece

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