Generation of tonalitic and dioritic magmas by coupled partial melting of gabbroic and metasedimentary rocks within the deep crust of the Famatinian magmatic arc, Argentina

The source regions of dioritic and tonalitic magmas have been identified in a deep crustal section of the Famatinian arc (Sierras Pampeanas of western Argentina). The source zones of intermediate igneous rocks are located at the transition between a gabbro-dominated mafic unit and a tonalite-dominat...

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Detalles Bibliográficos
Autores principales: Otamendi, J.E., Ducea, M.N., Tibaldi, A.M., Bergantz, G.W., de la Rosa, J.D., Vujovich, G.I.
Formato: JOUR
Materias:
Active continental margin
Famatinian arc
Magma genesis
Partial melts
Plutonic rocks
continental margin
crustal thickness
crystallization
diorite
emplacement
gabbro
island arc
leucogranite
mafic rock
magmatism
mantle process
mantle source
metasedimentary rock
partial melting
petrogenesis
tectonic evolution
tectonic setting
tonalite
Argentina
La Rioja [Argentina]
Sierra de Famatina
Sierras Pampeanas
South America
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_00223530_v50_n5_p841_Otamendi
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_00223530_v50_n5_p841_Otamendi
record_format dspace
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Active continental margin
Famatinian arc
Magma genesis
Partial melts
Plutonic rocks
continental margin
crustal thickness
crystallization
diorite
emplacement
gabbro
island arc
leucogranite
mafic rock
magmatism
mantle process
mantle source
metasedimentary rock
partial melting
petrogenesis
tectonic evolution
tectonic setting
tonalite
Argentina
La Rioja [Argentina]
Sierra de Famatina
Sierras Pampeanas
South America
spellingShingle Active continental margin
Famatinian arc
Magma genesis
Partial melts
Plutonic rocks
continental margin
crustal thickness
crystallization
diorite
emplacement
gabbro
island arc
leucogranite
mafic rock
magmatism
mantle process
mantle source
metasedimentary rock
partial melting
petrogenesis
tectonic evolution
tectonic setting
tonalite
Argentina
La Rioja [Argentina]
Sierra de Famatina
Sierras Pampeanas
South America
Otamendi, J.E.
Ducea, M.N.
Tibaldi, A.M.
Bergantz, G.W.
de la Rosa, J.D.
Vujovich, G.I.
Generation of tonalitic and dioritic magmas by coupled partial melting of gabbroic and metasedimentary rocks within the deep crust of the Famatinian magmatic arc, Argentina
topic_facet Active continental margin
Famatinian arc
Magma genesis
Partial melts
Plutonic rocks
continental margin
crustal thickness
crystallization
diorite
emplacement
gabbro
island arc
leucogranite
mafic rock
magmatism
mantle process
mantle source
metasedimentary rock
partial melting
petrogenesis
tectonic evolution
tectonic setting
tonalite
Argentina
La Rioja [Argentina]
Sierra de Famatina
Sierras Pampeanas
South America
description The source regions of dioritic and tonalitic magmas have been identified in a deep crustal section of the Famatinian arc (Sierras Pampeanas of western Argentina). The source zones of intermediate igneous rocks are located at the transition between a gabbro-dominated mafic unit and a tonalite-dominated intermediate unit. In the upper levels of the mafic unit mafic magmas intruded into metasedimentary wall-rocks, crystallized mainly as amphibole gabbronorite and caused the partial melting of the surrounding metasediments. In turn, the leucogranitic melts sourced from the metasedimentary rocks intruded into the newly crystallized but still hot mafic layers and catalysed the process of partial melting of the gabbroic plutonic rocks. The gabbroic rocks became mafic migmatites comprising amphibole-rich pyroxene-bearing mesosomes and leucotonalitic veins. Significantly, most of the mafic migmatites have isotopic compositions [87Sr/86Sr(T) < 0.7063 and εNd(T) = -0.94 to +2.24] similar to those of the gabbroic rocks and distinct from those of their complementary leucotonalitic veins [87Sr/86Sr(T) = 0.7075-0.7126 and εNd(T) < -2.65], providing evidence for the idea that melting of the mafic rocks was triggered by the intrusion of leucogranitic anatectic melts [87Sr/86Sr(T) = 0.715 and εNd(T) = -6.21]. Mass-balance calculations show that the model reaction plagioclase + amphibole + leucogranitic melt → leucotonalitic melt + clinopyroxene ± orthopyroxene can better explain the partial melting of the gabbroic rocks. Based on field observations, we argue that the coalescence of leucotonalitic veins in the mafic migmatites led to breakdown of the solid matrix to form melt-dominated leucotonalitic pools. However, the leucotonalitic veins that crystallized before leaving behind the mafic migmatitic rock are chemically (elemental and isotopic) more evolved than the dioritic and tonalitic rocks. We envisage that once detached from their source region the leucotonalitic magmas were able to react, commingle and mix with entrained fragments of both mafic and metasedimentary rocks. This process gave rise to melts that became tonalitic and dioritic magmas. This study concludes that the generation of intermediate magmas is a multistage process with three critical steps: (1) influx and emplacement of hydrous mafic magmas into a deep crust containing metasedimentary country rocks; (2) physically and chemically coupled melting of mafic and metasedimentary rocks, leading to the formation of a leucotonalitic vein and dyke system that coalesces to form leucotonalitic or tonalitic magma bodies; (3) retrogression of the leucotonalitic magmas by partially assimilating entrained fragments of their mafic and metasedimentary precursors. The dimensions of the source zone seem to be insufficient to generate crustal-scale volumes of intermediate igneous rocks. However, the Famatinian paleo-arc crust would expose only those magma source zones that were still active during the tectonic closure of the arc. Ultimately, a time-integrated perspective indicates that early active source zones were cannibalized during the downward expansion of the plutonic bodies already dominated by intermediate plutonic rocks. © The Author 2009. Published by Oxford University Press. All rights reserved.
format JOUR
author Otamendi, J.E.
Ducea, M.N.
Tibaldi, A.M.
Bergantz, G.W.
de la Rosa, J.D.
Vujovich, G.I.
author_facet Otamendi, J.E.
Ducea, M.N.
Tibaldi, A.M.
Bergantz, G.W.
de la Rosa, J.D.
Vujovich, G.I.
author_sort Otamendi, J.E.
title Generation of tonalitic and dioritic magmas by coupled partial melting of gabbroic and metasedimentary rocks within the deep crust of the Famatinian magmatic arc, Argentina
title_short Generation of tonalitic and dioritic magmas by coupled partial melting of gabbroic and metasedimentary rocks within the deep crust of the Famatinian magmatic arc, Argentina
title_full Generation of tonalitic and dioritic magmas by coupled partial melting of gabbroic and metasedimentary rocks within the deep crust of the Famatinian magmatic arc, Argentina
title_fullStr Generation of tonalitic and dioritic magmas by coupled partial melting of gabbroic and metasedimentary rocks within the deep crust of the Famatinian magmatic arc, Argentina
title_full_unstemmed Generation of tonalitic and dioritic magmas by coupled partial melting of gabbroic and metasedimentary rocks within the deep crust of the Famatinian magmatic arc, Argentina
title_sort generation of tonalitic and dioritic magmas by coupled partial melting of gabbroic and metasedimentary rocks within the deep crust of the famatinian magmatic arc, argentina
url http://hdl.handle.net/20.500.12110/paper_00223530_v50_n5_p841_Otamendi
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AT duceamn generationoftonaliticanddioriticmagmasbycoupledpartialmeltingofgabbroicandmetasedimentaryrockswithinthedeepcrustofthefamatinianmagmaticarcargentina
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spelling todo:paper_00223530_v50_n5_p841_Otamendi2023-10-03T14:31:55Z Generation of tonalitic and dioritic magmas by coupled partial melting of gabbroic and metasedimentary rocks within the deep crust of the Famatinian magmatic arc, Argentina Otamendi, J.E. Ducea, M.N. Tibaldi, A.M. Bergantz, G.W. de la Rosa, J.D. Vujovich, G.I. Active continental margin Famatinian arc Magma genesis Partial melts Plutonic rocks continental margin crustal thickness crystallization diorite emplacement gabbro island arc leucogranite mafic rock magmatism mantle process mantle source metasedimentary rock partial melting petrogenesis tectonic evolution tectonic setting tonalite Argentina La Rioja [Argentina] Sierra de Famatina Sierras Pampeanas South America The source regions of dioritic and tonalitic magmas have been identified in a deep crustal section of the Famatinian arc (Sierras Pampeanas of western Argentina). The source zones of intermediate igneous rocks are located at the transition between a gabbro-dominated mafic unit and a tonalite-dominated intermediate unit. In the upper levels of the mafic unit mafic magmas intruded into metasedimentary wall-rocks, crystallized mainly as amphibole gabbronorite and caused the partial melting of the surrounding metasediments. In turn, the leucogranitic melts sourced from the metasedimentary rocks intruded into the newly crystallized but still hot mafic layers and catalysed the process of partial melting of the gabbroic plutonic rocks. The gabbroic rocks became mafic migmatites comprising amphibole-rich pyroxene-bearing mesosomes and leucotonalitic veins. Significantly, most of the mafic migmatites have isotopic compositions [87Sr/86Sr(T) < 0.7063 and εNd(T) = -0.94 to +2.24] similar to those of the gabbroic rocks and distinct from those of their complementary leucotonalitic veins [87Sr/86Sr(T) = 0.7075-0.7126 and εNd(T) < -2.65], providing evidence for the idea that melting of the mafic rocks was triggered by the intrusion of leucogranitic anatectic melts [87Sr/86Sr(T) = 0.715 and εNd(T) = -6.21]. Mass-balance calculations show that the model reaction plagioclase + amphibole + leucogranitic melt → leucotonalitic melt + clinopyroxene ± orthopyroxene can better explain the partial melting of the gabbroic rocks. Based on field observations, we argue that the coalescence of leucotonalitic veins in the mafic migmatites led to breakdown of the solid matrix to form melt-dominated leucotonalitic pools. However, the leucotonalitic veins that crystallized before leaving behind the mafic migmatitic rock are chemically (elemental and isotopic) more evolved than the dioritic and tonalitic rocks. We envisage that once detached from their source region the leucotonalitic magmas were able to react, commingle and mix with entrained fragments of both mafic and metasedimentary rocks. This process gave rise to melts that became tonalitic and dioritic magmas. This study concludes that the generation of intermediate magmas is a multistage process with three critical steps: (1) influx and emplacement of hydrous mafic magmas into a deep crust containing metasedimentary country rocks; (2) physically and chemically coupled melting of mafic and metasedimentary rocks, leading to the formation of a leucotonalitic vein and dyke system that coalesces to form leucotonalitic or tonalitic magma bodies; (3) retrogression of the leucotonalitic magmas by partially assimilating entrained fragments of their mafic and metasedimentary precursors. The dimensions of the source zone seem to be insufficient to generate crustal-scale volumes of intermediate igneous rocks. However, the Famatinian paleo-arc crust would expose only those magma source zones that were still active during the tectonic closure of the arc. Ultimately, a time-integrated perspective indicates that early active source zones were cannibalized during the downward expansion of the plutonic bodies already dominated by intermediate plutonic rocks. © The Author 2009. Published by Oxford University Press. All rights reserved. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_00223530_v50_n5_p841_Otamendi

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