2015
DOI: 10.1016/j.precamres.2014.12.018
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Diachronic collision, slab break-off and long-term high thermal flux in the Brasiliano–Pan-African orogeny: Implications for the geodynamic evolution of the Mantiqueira Province

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Cited by 61 publications
(28 citation statements)
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“…In both margins, domain A is represented by the Pan‐African Araçuaí orogen in East Brazil and the Congo orogen in West Africa (Tack et al, ; Wiedemann et al, ). The Pan‐African orogenic structure was reactivated by early postcollisional extension that most likely restored the crust to close to its present‐day thickness of between 35 and 40 km (Bento dos Santos et al, ) but remained stable during Mesozoic rifting and passive margin formation. While there is no documented evidence for a role of orogenic inheritance, our model predictions allow the interpretation of a domain B where crustal thicknesses decrease to ~25 km accommodated by the reactivation of orogenic structures and initial development of new‐formed extensional shear zones (Figure b) with crustal thicknesses of ~25 km.…”
Section: Discussionmentioning
confidence: 99%
“…In both margins, domain A is represented by the Pan‐African Araçuaí orogen in East Brazil and the Congo orogen in West Africa (Tack et al, ; Wiedemann et al, ). The Pan‐African orogenic structure was reactivated by early postcollisional extension that most likely restored the crust to close to its present‐day thickness of between 35 and 40 km (Bento dos Santos et al, ) but remained stable during Mesozoic rifting and passive margin formation. While there is no documented evidence for a role of orogenic inheritance, our model predictions allow the interpretation of a domain B where crustal thicknesses decrease to ~25 km accommodated by the reactivation of orogenic structures and initial development of new‐formed extensional shear zones (Figure b) with crustal thicknesses of ~25 km.…”
Section: Discussionmentioning
confidence: 99%
“…The Araçuaí‐West Congo orogen is the northern part of the extensive Mantiqueira Province, which developed along the eastern margin of South America from Uruguay to central Brazil during the assembly of West Gondwana (e.g., Almeida et al, ; Bento dos Santos, Tassinari, & Fonseca, , and references therein) (Figure ). Altogether this province shows a complicated and long‐lived orogenic evolution, with an increasingly complex history of precollisional terrane accretion southward from the Araçuai, through the Ribeira and into the Dom Feliciano belt.…”
Section: The Araçuaí‐west Congo Orogenmentioning
confidence: 99%
“…In the Araçuaí‐West Congo orogen, the high temperatures, slow cooling, and excessive amount of melt in the hinterland (Figure b) require a heat source capable of maintaining a high temperature for a long time, more specifically to keep the temperature above 700°C from 600 to 480 Ma. This represents an unsolved question in the literature on the Araçuaí‐West Congo orogen, although vague references to radiogenic heat release from subducted metasediments and mantle upwelling, including subduction of a spreading ridge, slab break‐off, and upwelling of asthenospheric mantle, have been made (Bento dos Santos et al, ; Gradim et al, ; Tedeschi et al, ).…”
Section: Why So Hot? Why So Cold?mentioning
confidence: 99%
“…In this present work, the focus is on the Neoproterozoic Araçuaí orogen, which is the northern segment of the Ribeira-Araçuaí orogenic system formed during the Brasiliano/Pan-African Orogeny during the amalgamation of West Gondwana (Almeida et al, 1977;Bento dos Santos et al, 2015). This collisional belt experienced slow regional cooling, high temperature, and low pressure conditions (Petitgirard et al, 2009;Cavalcante et al, 2014;Moraes et al, 2015;Richter et al, 2016), where large volumes of magma were emplaced and deformed before solidification (Vauchez et al, 2007;Mondou et al, 2012;Cavalcante et al, 2014).…”
Section: I2 Objectivesmentioning
confidence: 99%