Geochronology of shear zones – A review

Shear zones play a major role in the deformation of the crust at a variety of scales, as expressions of strain localization during orogeny and rifting, and also as reactivated structures. They influence the geometry and evolution of orogenic belts and rifts, crustal rheology, magma ascent and emplac...

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Detalles Bibliográficos
Publicado: 2018
Materias:
Closure temperature
Deformation mechanisms
Isotopic diffusion
Mylonites
Strain localization
Thermochronology
closure temperature
deformation mechanism
diffusion
geochronology
mylonite
shear zone
strain partitioning
thermochronology
Acceso en línea:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00128252_v185_n_p665_Oriolo
http://hdl.handle.net/20.500.12110/paper_00128252_v185_n_p665_Oriolo
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Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
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spelling paper:paper_00128252_v185_n_p665_Oriolo2023-06-08T14:35:35Z Geochronology of shear zones – A review Closure temperature Deformation mechanisms Isotopic diffusion Mylonites Strain localization Thermochronology closure temperature deformation mechanism diffusion geochronology mylonite shear zone strain partitioning thermochronology Shear zones play a major role in the deformation of the crust at a variety of scales, as expressions of strain localization during orogeny and rifting, and also as reactivated structures. They influence the geometry and evolution of orogenic belts and rifts, crustal rheology, magma ascent and emplacement, and fluid flow. Consequently, assessing the timing of shear zone activity is crucial to reconstruct the tectonometamorphic evolution of the lithosphere. The interpretation of thermochronologic data from shear zones is, however, not straightforward. In the first place, closure temperatures depend on a number of factors (grain size, cooling rate, mineral composition and pressure, among others). On the other hand, deformation-related processes such as dynamic recrystallization, neocrystallization and fluid circulation seem to be crucial for isotopic systems and, thus, the obtained ages cannot be solely interpreted as a function of temperature in sheared rocks. For this reason, geochronologic data from shear zones might not only record cooling below closure temperature conditions but may also be affected by neo- or recrystallization, fluid-assisted deformation and inheritance of the protolith age(s). In order to robustly reconstruct P-T-ε-t paths of long-term crustal-scale shear zones, structural, microstructural and petrologic data from mylonites need to be integrated with ages from different thermochronometric systems. In addition, geochronologic data from associated intrusions and adjacent blocks can provide further irreplaceable constraints on the timing of deformation and its regional implications. One of the most challenging aspects that future lines of investigation should analyze is the quantitative evaluation of so far poorly explored aspects of isotopic diffusion, particularly the coupling with deformation processes, based on natural, theoretical and experimental data. Future works should also investigate the role of strain partitioning and localization processes in order to constrain the timing of deformation in different parts of a shear zone or in different branches of anastomosing shear zone networks. © 2018 Elsevier B.V. 2018 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00128252_v185_n_p665_Oriolo http://hdl.handle.net/20.500.12110/paper_00128252_v185_n_p665_Oriolo
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Closure temperature
Deformation mechanisms
Isotopic diffusion
Mylonites
Strain localization
Thermochronology
closure temperature
deformation mechanism
diffusion
geochronology
mylonite
shear zone
strain partitioning
thermochronology
spellingShingle Closure temperature
Deformation mechanisms
Isotopic diffusion
Mylonites
Strain localization
Thermochronology
closure temperature
deformation mechanism
diffusion
geochronology
mylonite
shear zone
strain partitioning
thermochronology
Geochronology of shear zones – A review
topic_facet Closure temperature
Deformation mechanisms
Isotopic diffusion
Mylonites
Strain localization
Thermochronology
closure temperature
deformation mechanism
diffusion
geochronology
mylonite
shear zone
strain partitioning
thermochronology
description Shear zones play a major role in the deformation of the crust at a variety of scales, as expressions of strain localization during orogeny and rifting, and also as reactivated structures. They influence the geometry and evolution of orogenic belts and rifts, crustal rheology, magma ascent and emplacement, and fluid flow. Consequently, assessing the timing of shear zone activity is crucial to reconstruct the tectonometamorphic evolution of the lithosphere. The interpretation of thermochronologic data from shear zones is, however, not straightforward. In the first place, closure temperatures depend on a number of factors (grain size, cooling rate, mineral composition and pressure, among others). On the other hand, deformation-related processes such as dynamic recrystallization, neocrystallization and fluid circulation seem to be crucial for isotopic systems and, thus, the obtained ages cannot be solely interpreted as a function of temperature in sheared rocks. For this reason, geochronologic data from shear zones might not only record cooling below closure temperature conditions but may also be affected by neo- or recrystallization, fluid-assisted deformation and inheritance of the protolith age(s). In order to robustly reconstruct P-T-ε-t paths of long-term crustal-scale shear zones, structural, microstructural and petrologic data from mylonites need to be integrated with ages from different thermochronometric systems. In addition, geochronologic data from associated intrusions and adjacent blocks can provide further irreplaceable constraints on the timing of deformation and its regional implications. One of the most challenging aspects that future lines of investigation should analyze is the quantitative evaluation of so far poorly explored aspects of isotopic diffusion, particularly the coupling with deformation processes, based on natural, theoretical and experimental data. Future works should also investigate the role of strain partitioning and localization processes in order to constrain the timing of deformation in different parts of a shear zone or in different branches of anastomosing shear zone networks. © 2018 Elsevier B.V.
title Geochronology of shear zones – A review
title_short Geochronology of shear zones – A review
title_full Geochronology of shear zones – A review
title_fullStr Geochronology of shear zones – A review
title_full_unstemmed Geochronology of shear zones – A review
title_sort geochronology of shear zones – a review
publishDate 2018
url https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00128252_v185_n_p665_Oriolo
http://hdl.handle.net/20.500.12110/paper_00128252_v185_n_p665_Oriolo
_version_ 1768546521945473024

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