A MASH Zone Revealed: the Mafic Complex of the Sierra Valle Fértil

Walker, B. A.; Bergantz, George W.; Otamendi, Juan E.; Ducea, Mihai N.; Cristofolini, Eber A.

doi:10.1093/petrology/egv057

Cited by 108 publications

(73 citation statements)

References 110 publications

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“…Karakas and Dufek, 2015) and thus call for fractionation as the primary means for producing silicic magmas (e.g. Jagoutz, 2010;Lee and Bachmann, 2014;Rioux et al, 2010;Walker et al, 2015). Whereas we do not contest that the latter may be the case in several geologic settings, we stress that the efficiency of assimilation is strictly dependent on the thermal evolution and the compositional and tectonic conditions of the intruded crust.…”

Section: Discussionmentioning

confidence: 73%

Production of hybrid granitic magma at the advancing front of basaltic underplating: Inferences from the Sesia Magmatic System (south-western Alps, Italy)

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Demarchi

et al. 2016

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Section: Discussionmentioning

confidence: 73%

Production of hybrid granitic magma at the advancing front of basaltic underplating: Inferences from the Sesia Magmatic System (south-western Alps, Italy)

Sinigoi

Quick

Demarchi

et al. 2016

Lithos

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“…The greater diversity of applied pressure‐estimation techniques for granitoids and paragneisses from the Garm massif (Al‐in‐Hbl, GASP, and pseudosection modeling) compared to granitoids from the Gissar batholith (only Al‐in‐Hbl) reflects the greater lithologic diversity of the Garm massif. We speculate that exposures of rare, deformed mafic and ultramafic rocks reported in the Garm massif [ Budanov , ; Brookfield , ] may represent the upper MASH zone of the Gissar arc [e.g., Walker et al , ].…”

Section: Discussionmentioning

confidence: 99%

Birth, life, and demise of the Andean–syn‐collisional Gissar arc: Late Paleozoic tectono‐magmatic‐metamorphic evolution of the southwestern Tian Shan, Tajikistan

et al. 2017

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The amalgamation of the Central Asian Orogenic Belt in the southwestern Tian Shan in Tajikistan is represented by tectono‐magmatic‐metamorphic processes that accompanied late Paleozoic ocean closure and collision between the Karakum‐Tarim and Kazakh‐Kyrgyz terranes. Integrated U‐Pb geochronology, thermobarometry, pseudosection modeling, and Hf geochemistry constrain the timing and petro‐tectonic nature of these processes. The Gissar batholith and the Garm massif represent an eastward, along‐strike increase in paleodepth from upper‐batholith (~21–7 km) to arc‐root (~36–19 km) levels of the Andean–syn‐collisional Gissar arc, which developed from ~323–288 Ma in two stages: (i) Andean, I‐type granitoid magmatism from ~323–306 Ma due to northward subduction of the Gissar back‐arc ocean basin under the Gissar microcontinent, which was immediately followed by (ii) syn‐collisional, I‐S‐type granitoid magmatism in the Gissar batholith and the Garm massif from ~304–288 Ma due to northward subduction/underthrusting of Karakum marginal‐continental crust under the Gissar microcontinent. A rapid isotopic pull‐up from ~288–286 Ma signals the onset of juvenile, alkaline‐syenitic, post‐collisional magmatism by ~280 Ma, which was driven by delamination of the Gissar arclogite root and consequent convective asthenospheric upwelling. Whereas M–HT/LP prograde metamorphism in the Garm massif (650–750°C/6–7 kbar) from ~310–288 Ma was associated with subduction‐magma inundation and crustal thickening, HT/LP heating and decompression to peak‐metamorphic temperatures (~800–820°C/6–4 kbar) at ~288 ± 6 Ma was driven by the transmission of a post‐collisional, mantle‐derived heat wave through the Garm‐massif crust.

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“…6A). Although, there is not much data (to our knowledge) on the actual thickness of the MASH zone, available studies suggest that it is most likely comprised between 1 and 10 km thick (e.g., Jackson et al, 2002;Walker et al, 2015). Jackson et al (2002) showed that 2 km was enough to strongly influence the compositional evolution of the magmatic products segregated from the MASH zone.…”

Section: Model Setup Of An Applicationmentioning

confidence: 99%

“…In migmatitic orthogneiss from the Gföhl Unit (Bohemian Massif), Hasalová et al (2008a) described 100-m scale pervasive flow from an external source produced migmatitic textures of high melt fraction. In the Ordovician Sierra Valle Fertil Complex of west-central Argentina, Walker et al (2015) studied an exposed lower crustal arc section. Based on petrological and geochemical studies, the authors show that the mafic section (mainly gabbronorites) was the locus of prolonged periods of (cyclic) magma injection, crystallization, and assimilation, with very efficient melt segregation at the kilometer scale.…”

Section: Introductionmentioning

confidence: 99%

Interaction between mantle-derived magma and lower arc crust: quantitative reactive melt flow modelling using STyx

Riel

Bouilhol

Hunen

et al. 2018

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The magmatic processes occurring in the lowermost arc crust play a major role in the evolution of mantle-wedge-derived melt. Geological evidence indicates that mantle-derived magmas and in-situ products of lower crust partial melting are reacting in a pervasive melt system and are eventually extracted towards higher levels of the crust. Resolving the relative contribution of mantle-derived magma and partial melting products of pre-existing crust is essential to: (1) quantify crustal growth rate; (2) better understand the compositional range of arc magmatic series; and (3) constrain the chemical differentiation of the lower crust. In this study, we present STyx, a new modelling tool, coupling melt and heat flow with petrology to explore the dynamics of storage, transfer and hybridization of melts in complex liquid/rock systems. We perform three models representing a magmatic event affecting an amphibolitic lower arc crust in order to quantify the relative contribution between partial melting of the pre-existing crust and fractional crystallization from mantle-derived hydrous-magma. Our models demonstrate that most of the differentiated arc crust is juvenile, deriving from the differentiation of mantle melts, and that pre-existing crust does not significantly contribute to the total thickness of magmatic products.

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A MASH Zone Revealed: the Mafic Complex of the Sierra Valle Fértil

Cited by 108 publications

References 110 publications

Production of hybrid granitic magma at the advancing front of basaltic underplating: Inferences from the Sesia Magmatic System (south-western Alps, Italy)

Production of hybrid granitic magma at the advancing front of basaltic underplating: Inferences from the Sesia Magmatic System (south-western Alps, Italy)

Birth, life, and demise of the Andean–syn‐collisional Gissar arc: Late Paleozoic tectono‐magmatic‐metamorphic evolution of the southwestern Tian Shan, Tajikistan

Interaction between mantle-derived magma and lower arc crust: quantitative reactive melt flow modelling using STyx

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