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6. Silurian inverted Barrovian-type metamorphism in the Western Sierras Pampeanas (Argentina): a case of top to bottom heating?

Author

Verdecchia, Sebastián O., Casquet, Cesar, Baldo, Edgardo G., Larrovere, Mariano A., Lembo Wuest, Carlos I., Benítez, Manuela E., Ramacciotti, Carlos D., Murra, Juan A., Pankhurst, Robert J., Verdecchia, Sebastián O., Casquet, Cesar, Baldo, Edgardo G., Larrovere, Mariano A., Lembo Wuest, Carlos I., Benítez, Manuela E., Ramacciotti, Carlos D., Murra, Juan A., and Pankhurst, Robert J.

Abstract

This paper focuses on one orogenic belt that formed during the Rinconada phase on the final stage of the Famatinian orogeny, between 445 and 410 Ma, which is well exposed at Sierra de Ramaditas and neighbouring ranges in western Argentina. The Ramaditas Complex is formed by metasedimentary and meta-ultrabasic rocks and amphibolites. This complex forms the upper nappe of a thrust stack resulting from westward thrusting. Deformation consists of an early high-temperature S1 foliation (stromatic migmatites), coeval with thrusting and metamorphism. Metamorphism attained peak P–T conditions of 6.0–6.9 kbar and 795–810 °C, at c. 440 Ma, i.e. coincident with the Rinconada orogenic phase. The lower unit and intermediate nappes crop out in the nearby sierras of Maz and Espinal and underwent low- to medium-grade Silurian metamorphism, respectively, together with the upper nappe, defining an inverted Barrovian-type metamorphism with T decreasing and P increasing downwards across the thrust stack (i.e. westward). We argue that the Rinconada orogenic phase developed near the continental margin of SW Gondwana, during a magmatic lull following accretion of the Precordillera terrane to the continental margin at c. 470 Ma. The active margin jumped to the west after accretion, and flat-slab subduction resumed in the early Silurian, provoking thrusting and imbrication of nappe stack under the still hot root (800–900 °C) of the older Famatinian magmatic arc. This ‘hot-iron’ process explains both the inverted Barrovian-type metamorphism and the missing overburden of 21 to 24 km implied by the P estimate.

Published
2023

7. Silurian inverted Barrovian-type metamorphism in the Western Sierras Pampeanas (Argentina): a case of top to bottom heating?

Author

0000-0002-1912-3911, Casquet, Cesar [0000-0002-1868-870X], #NODATA#, 0000-0002-0317-0019, Verdecchia, Sebastián O., Casquet, Cesar, Baldo, Edgardo G., Larrovere, Mariano A., Lembo Wuest, Carlos I., Benítez, Manuela E., Ramacciotti, Carlos D., Murra, Juan A., Pankhurst, Robert J., 0000-0002-1912-3911, Casquet, Cesar [0000-0002-1868-870X], #NODATA#, 0000-0002-0317-0019, Verdecchia, Sebastián O., Casquet, Cesar, Baldo, Edgardo G., Larrovere, Mariano A., Lembo Wuest, Carlos I., Benítez, Manuela E., Ramacciotti, Carlos D., Murra, Juan A., and Pankhurst, Robert J.

Abstract

This paper focuses on one orogenic belt that formed during the Rinconada phase on the final stage of the Famatinian orogeny, between 445 and 410 Ma, which is well exposed at Sierra de Ramaditas and neighbouring ranges in western Argentina. The Ramaditas Complex is formed by metasedimentary and meta-ultrabasic rocks and amphibolites. This complex forms the upper nappe of a thrust stack resulting from westward thrusting. Deformation consists of an early high-temperature S1 foliation (stromatic migmatites), coeval with thrusting and metamorphism. Metamorphism attained peak P-T conditions of 6.0-6.9 kbar and 795-810 °C, at c. 440 Ma, i.e. coincident with the Rinconada orogenic phase. The lower unit and intermediate nappes crop out in the nearby sierras of Maz and Espinal and underwent low- to medium-grade Silurian metamorphism, respectively, together with the upper nappe, defining an inverted Barrovian-type metamorphism with T decreasing and P increasing downwards across the thrust stack (i.e. westward). We argue that the Rinconada orogenic phase developed near the continental margin of SW Gondwana, during a magmatic lull following accretion of the Precordillera terrane to the continental margin at c. 470 Ma. The active margin jumped to the west after accretion, and flat-slab subduction resumed in the early Silurian, provoking thrusting and imbrication of nappe stack under the still hot root (800-900 °C) of the older Famatinian magmatic arc. This 'hot-iron' process explains both the inverted Barrovian-type metamorphism and the missing overburden of 21 to 24 km implied by the P estimate.

Published
2023

12. Late Famatinian (440–410 Ma) overprint of Grenvillian metamorphism in Grt‐St schists from the Sierra de Maz (Argentina): Phase equilibrium modelling, geochronology, and tectonic significance

Author

Verdecchia, Sebastián O., Ramacciotti, Carlos D., Casquet, Cesar, Baldo, Edgardo G., Murra, Juan A., Pankhurst, Robert J., Verdecchia, Sebastián O., Ramacciotti, Carlos D., Casquet, Cesar, Baldo, Edgardo G., Murra, Juan A., and Pankhurst, Robert J.

Abstract

The analysis of major and trace elements in zoned minerals is useful for deciphering parts of the tectonothermal evolution of polymetamorphic tarrain. We applied this approach to the Maz Metasedimentary Series in Western Sierras Pampeanas of Argentina, where polymetamorphism resulted in the overprinting of a Grenvillian basement (the Maz Complex) during the pervasive Rinconada tectonic phase of the Famatinian orogeny. The older metamorphism (M1) is assigned to the youngest Grenvillian metamorphic event recognized in this basement at c. 1035 Ma, whereas the Rinconada metamorphism (M2) was Silurian to early Devonian, essentially between 440 and 410 Ma. The latter resulted from oceanward migration of the orogenic front relative to earlier late Cambrian to Ordovician (490–470 Ma) tectonic phases of the Famatinian orogeny. The M1 and M2 metamorphic events have been recognized in a staurolite-garnet schist from the Maz Metasedimentary Series. Most metamorphic minerals from this rock were formed during the M2 event which was of the Barrovian type (±kyanite). Part of the metamorphic P–T evolution is recorded in the complex compositional zoning of garnet porphyroblasts. Three types of garnet were identified based on texture and chemistry, including trace elements (REEs). Phase equilibrium analysis, compositional isopleth, and multi-equilibrium thermobarometry were applied in order to establish the P–T history. M1 is represented by preservation of Grt1 ± Kfs ± Sil, with peak P–T condition of 790°C and 5.2 kbar, that is, granulite facies. This early metamorphic event was related to a deformational D1 episode represented by a relict S1 foliation. The latter is preserved as aligned inclusions in staurolite porphyroblasts and as relics of an older crenulated foliation in microlithons from the matrix. M2 followed a clockwise P–T path with three mineral growth stages. The earliest occurred at ~585°C and ~8.7 kbar and is represented by Grt2 ± St1 ± Bt1 + Qz. Grt2 was partially coeva

Published
2022

15. The continental crust of Northeastern Patagonia

Author

Rapela, Carlos W., Pankhurst, Robert J., Rapela, Carlos W., and Pankhurst, Robert J.

Abstract

The basement of northeastern Patagonia is characterized by Early Paleozoic igneous and metamorphic rocks that do not crop out in the central, western and Andean sectors of the North Patagonian Massif. A review of U-Pb geochronology, geochemistry, and the Nd, Sr, Hf and O isotope signature of the early Cambrian and early Ordovician magmatic rocks supports the hypothesis that the continental crust of northeastern Patagonia was essentially continuous with that of the Eastern Sierras Pampeanas in early Cambrian times. Mesoproterozoic lower crust is also inferred for this sector. New zircon Hf and O analyses of early Cambrian (Pampean) granites in the Sierras Pampeanas are indistinguishable from those of Cambrian granites in NE Patagonia, indicating an important crustal component in the source. The detrital zircon age patterns of the inferred basement are also similar in the two regions, strongly suggesting a southern Kalahari provenance. A modified hypothesis to explain the continuity of NE Patagonia with the Pampean belt of the Sierras Pampeanas during early Cambrian times, as well as their SW Gondwana geological affinity, is to consider this entire belt as an outboard sector of the mid-Cambrian rifting observed along the South America–South Africa–Weddell Sea margin. The detached sector would then have become juxtaposed against the Río de la Plata craton across the right-lateral Córdoba fault in late Cambrian times.

Published
2020

16. U–Pb SHRIMP detrital zircon dating of metamorphic rocks in north–central Chile (28°–33°S): Evidence for Carboniferous and Triassic metamorphism in a subduction setting

Author

Herve, Francisco, Calderon, Mauricio, Fanning, Christopher Mark, Pankhurst, Robert J., Navarro, J., Herve, Francisco, Calderon, Mauricio, Fanning, Christopher Mark, Pankhurst, Robert J., and Navarro, J.

Abstract

U–Pb SHRIMP detrital zircon dating of ten samples of metamorphic “basement” rocks in north-central Chile and one granitic rock, improve knowledge of sedimentary, metamorphic and plutonic events in this segment of the Andean margin. The oldest possible sedimentation ages (Ordovician) come from a micaschist at Huentelauquén (477 Ma) and a granofels from a migmatite at Las Cruces (470 Ma) whose garnet-bearing granitic neosome (ca. 320 Ma) is essentially coetaneous with the extensive Coast Range Batholith. The rest of the samples show probable Carboniferous or Late Triassic maximum depositional ages. The late Paleozoic low-to-medium grade metasedimentary components of the basement, interpreted as forming part of a paleo-accretionary complex, have detrital zircon age patterns with prominent Famatinian and Grenville-age peaks; these are much less prominent in the Late Triassic rocks. The latter were deformed and metamorphosed shortly after their deposition, although some do not show visible evidence of metamorphism. Contemporaneous Triassic sedimentary, metamorphic and igneous events are recorded in Mejillones Peninsula (22°S) and in the Chonos archipelago (44°–47°S) but not in the 34°–42°S central Chile sector of the fossil accretionary complex. These events predate generalized Jurassic subduction beneath the western Gondwana continental margin that initiated the Andean orogenic cycle.

Published
2020

18. O - Sr - Nd isotope constraints on the origin of intermediate magmas in the Famatinian arc, NW Argentina

Author

Alasino, Pablo H., Casquet, César, Galindo, Carmen, Rapela, Carlos W., Pankhurst, Robert J., Dahlquist, J., Recio, Clemente, and Baldo, Edgardo G.

Abstract

Trabajo presentado en el XV Congreso Geológico Chileno, celebrado en Concepción (Chile), del 18 al 23 de Noviembre de 2018, The origin of Early Ordovician Famatinian intermediate igneous rocks is controversial and has been ascribed to either (i) partial melting of a Proterozoic crust-lithospheric mantle section, or (ii) interaction between mafic magmas and supracrustal materials. We explore the new geochemical evidence from 35 bulk rock O-Sr-Nd isotope compositions from three crustal sections of the arc, a relatively deep one (LC) represented by the Sierra de Valle Fértil, a mid-crustal section (MC) in the Western Sierra de Famatina and SW Sierra de Velasco, and an upper crustal section (UC) in the Sierra de Los Llanos, central Sierra de Famatina and Sierra de Narváez. δ18O values allow us to distinguish four main groups: G1 represented by two meta-gabbros with low δ18O values (ca. +5.3‰), one from LC and one from MC; G2 comprising a wide range of rocks (10 meta-gabbros/gabbros, eight diorite-tonalitegranodiorite samples, three granites and two rhyolites) of all levels with δ18O values from +6.6 to +10‰; G3 consists of two hybrids of MC with δ18O values of +8.7 and +9.9‰ formed by interaction between partially molten country rocks and metaluminous tonalitic magmas; and G4 formed by five Ordovician metasedimentary rocks and three Crd-bearing granites of the three levels with the highest δ18O values (+10.6 to +13.8‰). There is no major difference in isotope composition between mafic G2 rocks thought to be derived from a metasomatized sub-arc mantle (δ18O= +7.4 to +9.4‰, 87Sr/ 86Sri= 0.706 to 0.709 and εNdi = 3.7 to 5.8) and intermediate rocks of the same group (δ18O= +6.6 to +9‰, 87Sr/86Sri = 0.705 to 0.709 and εNdi = 0.5 to 4.4, except for two LC samples with values about +9.5‰, 0.711 and 5). G2 granites and rhyolites show higher values of δ18O (+8.5 to +10‰) but similar 87Sr/86Sri (0.706 to 0.709) and εNdi (ca. 3.5). Remarkably, the range of δ18O values from +6.6 to +10‰ for most G2 samples does not correlate with aluminum saturation index (ASI). Except for some G2 tonalite samples of LC and G3 hybrids from thermal aureoles, the ASI values remain unchanged within each group of rocks. Generation of the G2 intermediate rocks cannot be related to the bulk assimilation of partially melted metasedimentary rocks of G4 through partial melting by mafic intrusions. We conclude that sub-arc mantle melting was the main process involved in the formation of the metaluminous G2 intermediate rocks with restricted contamination (≤ 20%) by continental crust melts.

Published
2018

19. The country rocks of Devonian magmatism in the North Patagonian Massif and Chaitenia

Author

Hervé, Francisco, Calderón, Mauricio, Fanning, C. Mark, Pankhurst, Robert J., Rapela, Carlos W., and Quezada, Paulo

Subjects
North Patagonian Massif, Metamorphic complexes, Devónico, Devonian, Complejos metamórficos, Edades U-Pb en circones, Chaitenia, U-Pb zircon ages, Macizo Norpatagónico
Abstract

Previous work has shown that Devonian magmatism in the southern Andes occurred in two contemporaneous belts: one emplaced in the continental crust of the North Patagonian Massif and the other in an oceanic island arc terrane to the west, Chaitenia, which was later accreted to Patagonia. The country rocks of the plutonic rocks consist of metasedimentary complexes which crop out sporadically in the Andes on both sides of the Argentina-Chile border, and additionally of pillow metabasalts for Chaitenia. Detrital zircon SHRIMP U-Pb age determinations in 13 samples of these rocks indicate maximum possible depositional ages from ca. 370 to 900 Ma, and the case is argued for mostly Devonian sedimentation as for the fossiliferous Buill slates. Ordovician, Cambrian-late Neoproterozoic and “Grenville-age” provenance is seen throughout, except for the most westerly outcrops where Devonian detrital zircons predominate. Besides a difference in the Precambrian zircon grains, 76% versus 25% respectively, there is no systematic variation in provenance from the Patagonian foreland to Chaitenia, so that the island arc terrane must have been proximal to the continent: its deeper crust is not exposed but several outcrops of ultramafic rocks are known. Zircons with devonian metamorphic rims in rocks from the North Patagonian Massif have no counterpart in the low metamorphic grade Chilean rocks. These Paleozoic metasedimentary rocks were also intruded by Pennsylvanian and Jurassic granitoids. RESUMEN Trabajos anteriores han demostrado que el magmatismo devónico en los Andes meridionales se produjo en dos cinturones contemporáneos: uno emplazado en la corteza continental del Macizo Norpatagónico y el otro, hacia el oeste, en un arco de islas oceánico, Chaitenia, que más tarde se acrecionó a Gondwana. Las rocas hospedantes de las rocas plutónicas consisten en complejos metasedimentarios que aparecen esporádicamente en los Andes a ambos lados de la frontera entre Argentina y Chile, y adicionalmente de metabasaltos de almohadilla en Chaitenia. Las determinaciones de la edad de U-Pb de circones detríticos en 13 muestras de estas rocas metasedimentarias indican edades deposicionales máximas posibles de ca. 370 a 900 Ma, y se argumenta que la sedimentación es principalmente del Devónico similar a las pizarras fosilíferas de Buill. Procedencia del Ordovícico, del Cámbrico-tardío a Neoproterozoico y “Grenville” se ve en todas las rocas, a excepción de los afloramientos más occidentales donde predominan los zircones detríticos del Devónico. Además de una diferencia en los granos de zircón precámbricos, 76% versus 25% respectivamente, no hay variación sistemática en la procedencia del antepaís patagónico a Chaitenia, por lo que el arco de islas debe haber sido proximal al continente: su corteza más profunda no está expuesta pero se conocen varios afloramientos de rocas ultramáficas. Los bordes metamórficos desarrollados durante el Devónico en circones de las rocas del Macizo Norpatagónico no tienen su equivalente en los circones de las rocas metamórficas de bajo grado del sector chileno. Estas rocas metasedimentarias paleozoicas también fueron intruidas por granitoides del Pennsylvaniano y Jurásico.

Published
2018

20. The Famatinian cordilleran magmatism in southern South America resulting from lithosphere reworking?

Author

Rapela, Carlos W., Pankhurst, Robert J., Casquet, César, Dahlquist, J., Fanning, M., Baldo, Edgardo G., Galindo, Carmen, Alasino, Pablo H., Ramacciotti, Carlos D., Verdecchia, Sebastián O., Murra, J. A., and Basei, Miguel A. S.

Abstract

Trabajo presentado en el XV Congreso Geológico Chileno, celebrado en Concepción (Chile), del 18 al 23 de Noviembre de 2018, Along the proto-Pacific margin of Gondwana, from Venezuela to northeastern Patagonia, the Early–Middle Ordovician Famatinian orogeny was the first orogenic event following assembly of the supercontinent. Magmatism is mostly restricted to the interval 463±4 to 486±7 Ma, with the most intense period of emplacement between 468 and 472 Ma constituting a magmatic flare-up. Granitoid emplacement in both northeastern Patagonia and the Cordon de Lila (Puna Altiplano, Chile) was effectively synchronous with that in the Sierras Pampeanas, defining a continuous belt. Combined geochemical and isotopic data (whole-rock Sr, Nd; Hf, O in zircon) indicate that the source of calcic metaluminous suites is the subcontinental lithosphere –both mantle and mafic lower crust– with variable contamination by the Early Paleozoic metasedimentary country rocks. The lithospheric mantle involved is assumed to underlie the outcropping 1330–1030 Ma Grenville-age basement of the Western Domain, which exhibits tectonic characteristics of active continental margin in the north and oceanic arc-back arc in the south. The latter sector is the potential source of some minor Famatinian igneous rocks with less evolved isotopic compositions, although a restricted asthenospheric addition cannot be discarded in this case. Minor peraluminous granites are spatially associated with the metaluminous sequence, but major highly peraluminous batholiths occur on the eastern flank of the Central Domain. Field relations and geochemical/isotopic evidence indicate that the most obvious source of these crustal melts was the very thick post-early Cambrian metasedimentary sequence comprising the host country rocks. Although asthenospheric mantle was a necessary heat source for lithospheric melting, its material contribution to the growth of Early Paleozoic crust was apparently very minor. Recycling of Mesoproterozoic lithosphere, including the subcontinental mantle, coupled with crustal melting of Early Paleozoic metasedimentary sequences, accounts for most of the Famatinian orogenic magmatism. Consistent results from the Central Andes and East Antarctica confirm that the early stages of the Terra Australis orogen in SW Gondwana were dominated by lithospheric reworking processes.

Published
2018

21. A review of the Famatinian Ordovician magmatism in southern South America: evidence of lithosphere reworking and continental subduction in the early proto-Andean margin of Gondwana

Author

Consejo Nacional de Investigaciones Científicas y Técnicas (Argentina), Fondo para la Investigación Científica y Tecnológica (Argentina), Ministerio de Economía y Competitividad (España), Universidad Complutense de Madrid, Banco Santander, Rapela, Carlos W., Pankhurst, Robert J., Casquet, César, Dahlquist, J., Fanning, M., Baldo, Edgardo G., Galindo, Carmen, Alasino, Pablo H., Ramacciotti, Carlos D., Verdecchia, Sebastián O., Murra, J. A., Basei, Miguel A. S., Consejo Nacional de Investigaciones Científicas y Técnicas (Argentina), Fondo para la Investigación Científica y Tecnológica (Argentina), Ministerio de Economía y Competitividad (España), Universidad Complutense de Madrid, Banco Santander, Rapela, Carlos W., Pankhurst, Robert J., Casquet, César, Dahlquist, J., Fanning, M., Baldo, Edgardo G., Galindo, Carmen, Alasino, Pablo H., Ramacciotti, Carlos D., Verdecchia, Sebastián O., Murra, J. A., and Basei, Miguel A. S.

Abstract

Along the proto-Pacific margin of Gondwana, from Venezuela to northeastern Patagonia, the Early–Middle Ordovician Famatinian orogeny was the first orogenic event following assembly of the supercontinent. Previous isotope studies of the igneous and (meta-)sedimentary rocks of southwestern Gondwana yield ambiguous implications for the role of juvenile mantle addition during the early crustal growth at the supercontinental margin. To interpret the geological and tectonic evolution of the orogen and the magma sources in different episodes we look at evidence from a large area of southern South America, including the 700 × 600 km type sector of the orogen in the Sierras Pampeanas (27°–33°S), the Precordillera, and northeastern Patagonia. Previous geological, geochemical and geochronological results are reviewed together with new U—Pb SHRIMP crystallization ages, 177Hf/176Hf and 18O/16O data for dated zircon, and whole-rock Sr and Nd isotope compositions., Four geological domains are recognized in the Sierras Pampeanas (Western, Central, Eastern and Foreland Famatinian domains). Magmatism is mostly restricted to the interval 463 ± 4 to 486 ± 7 Ma, with the most intense period of emplacement between 468 and 472 Ma constituting a magmatic flare-up. Granitoid emplacement in both northeastern Patagonia and the Cordon de Lila (Puna Altiplano, Chile) was effectively synchronous with that in the Sierras Pampeanas, defining a continuous belt. Combined geochemical and isotopic data (whole-rock Sr, Nd; Hf, O in zircon) indicate that the source of calcic metaluminous suites is the subcontinental lithosphere – both mantle and mafic lower crust – with variable contamination by the Early Paleozoic metasedimentary country rocks. The lithospheric mantle involved is assumed to underlie the outcropping 1330–1030 Ma age basement of the Western Domain, which exhibits tectonic characteristics of active continental margin in the north and oceanic arc-back arc in the south. The latter sector is the potential source of some minor Famatinian igneous rocks with less evolved isotopic compositions, although a restricted asthenospheric addition cannot be discarded in this case. Minor peraluminous granites are spatially associated with the metaluminous sequence, but major highly-peraluminous batholiths occur on the eastern flank of the Central Domain. Field relations and geochemical/isotopic evidence indicate that the most obvious source of these crustal melts was the very thick post-early Cambrian metasedimentary sequence comprising the host country rocks., Episodic tectono-magmatic evolution of the Famatinian magmatic belt in two overlapping stages is invoked to explain different characteristics in the four recognized domains in the type sector: • ca. 474–486? Ma, roll-back stage. This is a mainly extensional interval involving asthenospheric upwelling and thinning of the subcontinental mantle; full development of the marine ensialic basins and early emplacement of both metaluminous granites and highly-peraluminous batholiths in the Central and Eastern Famatinian domains. Trondhjemite plutons with an adakitic signature were emplaced in the Foreland Domain • ca. 468–472 Ma, slab break-off stage. Steepening of the oceanic slab and arc migration to the southwest ended with slab break-off due to subduction of continental crust during continental collision with the Precordillera terrane. This stage produced voluminous metaluminous magmatism at the western edge of the Central Domain (the flare-up episode), K-bentonites in the Precordillera, leucogranites in the Western Domain and scattered metaluminous and peraluminous plutons in all Famatinian domains. Both slab roll-back and break-off stages developed during a high-T regime typical of hot orogens. Although asthenospheric mantle was a necessary heat source for lithospheric melting, its material contribution to the growth of Early Paleozoic crust was apparently very minor. Recycling of Mesoproterozoic lithosphere, including the subcontinental mantle, coupled with crustal melting of Early Paleozoic metasedimentary sequences, accounts for most Famatinian magmatism. Comparable results from the Central Andes and East Antarctica confirm that the early stages of the Terra Australis orogen in SW Gondwana were dominated by lithospheric reworking processes.

Published
2018

22. A review of the Famatinian Ordovician magmatism in southern South America: evidence of lithosphere reworking and continental subduction in the early proto-Andean margin of Gondwana

Author

Rapela, Carlos W, Pankhurst, Robert J, Casquet, Cesar, Dahlquist, Juan A., Fanning, Christopher Mark, Baldo, Edgardo, Galindo, Carmen, Alasino, Pablo H., Ramacciotti, Carlos D., Verdecchia, Sebastian O., Murra, Juan A., Basei, Miguel Angelo Stipp, Rapela, Carlos W, Pankhurst, Robert J, Casquet, Cesar, Dahlquist, Juan A., Fanning, Christopher Mark, Baldo, Edgardo, Galindo, Carmen, Alasino, Pablo H., Ramacciotti, Carlos D., Verdecchia, Sebastian O., Murra, Juan A., and Basei, Miguel Angelo Stipp

Abstract

Along the proto-Pacific margin of Gondwana, from Venezuela to northeastern Patagonia, the Early–Middle Ordovician Famatinian orogeny was the first orogenic event following assembly of the supercontinent. Previous isotope studies of the igneous and (meta-)sedimentary rocks of southwestern Gondwana yield ambiguous implications for the role of juvenile mantle addition during the early crustal growth at the supercontinental margin. To interpret the geological and tectonic evolution of the orogen and the magma sources in different episodes we look at evidence from a large area of southern South America, including the 700 × 600 km type sector of the orogen in the Sierras Pampeanas (27°–33°S), the Precordillera, and northeastern Patagonia. Previous geological, geochemical and geochronological results are reviewed together with new U—Pb SHRIMP crystallization ages, 177Hf/176Hf and 18O/16O data for dated zircon, and whole-rock Sr and Nd isotope compositions.

Published
2018

23. A Cambrian mixed carbonate–siliciclastic platform in SW Gondwana: evidence from the Western Sierras Pampeanas (Argentina) and implications for the early Paleozoic paleogeography of the proto-Andean margin

Author

Consejo Nacional de Investigaciones Científicas y Técnicas (Argentina), Fondo para la Investigación Científica y Tecnológica (Argentina), Secretaría de Ciencia y Técnica de la Nación (Argentina), Ministerio de Ciencia e Innovación (España), Ministerio de Economía y Competitividad (España), Universidad Complutense de Madrid, Banco Santander, Ramacciotti, Carlos D., Casquet, César, Baldo, Edgardo G., Galindo, Carmen, Pankhurst, Robert J., Verdecchia, Sebastián O., Rapela, Carlos W., Fanning, M., Consejo Nacional de Investigaciones Científicas y Técnicas (Argentina), Fondo para la Investigación Científica y Tecnológica (Argentina), Secretaría de Ciencia y Técnica de la Nación (Argentina), Ministerio de Ciencia e Innovación (España), Ministerio de Economía y Competitividad (España), Universidad Complutense de Madrid, Banco Santander, Ramacciotti, Carlos D., Casquet, César, Baldo, Edgardo G., Galindo, Carmen, Pankhurst, Robert J., Verdecchia, Sebastián O., Rapela, Carlos W., and Fanning, M.

Abstract

The Western Sierras Pampeanas (WSP) of Argentina record a protracted geological history from the Mesoproterozoic assembly of the Rodinia supercontinent to the early Paleozoic tectonic evolution of SW Gondwana. Two well-known orogenies took place at the proto-Andean margin of Gondwana in the Cambrian and the Ordovician, i.e., the Pampean (545–520 Ma) and Famatinian (490–440 Ma) orogenies, respectively. Between them, an extensive continental platform was developed, where mixed carbonate–siliciclastic sedimentation occurred. This platform was later involved in the Famatinian orogeny when it underwent penetrative deformation and metamorphism. The platform apparently extended from Patagonia to northwestern Argentina and the Eastern Sierras Pampeanas, and has probable equivalents in SW Africa, Peru, and Bolivia. The WSP record the outer (deepest) part of the platform, where carbonates were deposited in addition to siliciclastic sediments. Detrital zircon U–Pb SHRIMP ages from clastic metasedimentary successions and Sr-isotope compositions of marbles from the WSP suggest depositional ages between ca. 525 and 490 Ma. The detrital zircon age patterns further suggest that clastic sedimentation took place in two stages. The first was sourced mainly from re-working of the underlying Neoproterozoic metasedimentary rocks and the uplifted core of the early Cambrian Pampean orogen, without input from the Paleoproterozoic Río de la Plata craton. Sediments of the second stage resulted from the erosion of the still emerged Pampean belt and the Neoproterozoic Brasiliano orogen in the NE with some contribution from the Río de la Plata craton. An important conclusion is that the WSP basement was already part of SW Gondwana in the early Cambrian, and not part of the exotic Precordillera/Cuyania terrane, as was previously thought.

Published
2018

24. Review of the Cambrian Pampean orogeny of Argentina; a displaced orogen formerly attached to the Saldania Belt of South Africa?

Author

Consejo Nacional de Investigaciones Científicas y Técnicas (Argentina), Fondo para la Investigación Científica y Tecnológica (Argentina), Ministerio de Economía y Competitividad (España), Universidad Complutense de Madrid, Banco Santander, Casquet, César, Dahlquist, J., Verdecchia, Sebastián O., Baldo, Edgardo G., Galindo, Carmen, Rapela, Carlos W., Pankhurst, Robert J., Morales Cámera, Matías M., Murra, J. A., Fanning, M., Consejo Nacional de Investigaciones Científicas y Técnicas (Argentina), Fondo para la Investigación Científica y Tecnológica (Argentina), Ministerio de Economía y Competitividad (España), Universidad Complutense de Madrid, Banco Santander, Casquet, César, Dahlquist, J., Verdecchia, Sebastián O., Baldo, Edgardo G., Galindo, Carmen, Rapela, Carlos W., Pankhurst, Robert J., Morales Cámera, Matías M., Murra, J. A., and Fanning, M.

Abstract

The Pampean orogeny of northern Argentina resulted from Early Cambrian oblique collision of the Paleoproterozoic-Mesoproterozoic MARA block, formerly attached to Laurentia, with the Gondwanan Kalahari and Rio de la Plata cratons. The orogen is partially preserved because it is bounded by the younger Córdoba Fault on the east and by the Los Túneles-Guacha Corral Ordovician shear zone on the west. In this review we correlate the Pampean Belt with the Saldania orogenic belt of South Africa and argue that both formed at an active continental margin fed with sediments coming mainly from the erosion of the Brasiliano–Pan-African and East African–Antarctica orogens between ca. 570 and 537 Ma (Puncoviscana Formation) and between 557 and 552 Ma (Malmesbury Group) respectively. Magmatic arcs (I-type and S-type granitoids) formed at the margin between ca. 552 and 530 Ma. Further right-lateral oblique collision of MARA between ca. 530 and 520 Ma produced a westward verging thickened belt. This involved an upper plate with high P/T metamorphism and a lower plate with high-grade intermediate to high P/T metamorphism probably resulting from crustal delamination or root foundering. The Neoproterozoic to Early Cambrian sedimentary cover of MARA that was part of the lower plate is only recognized in the high-grade domain along with a dismembered mafic–ultramafic ophiolite probably obducted in the early stages of collision. Uplift was fast in the upper plate and slower in the lower plate. Eventually the Saldania and Pampean belts detached from each other along the right-lateral Córdoba Fault, juxtaposing the Rio de la Plata craton against the internal high-grade zone of the Pampean belt.

Published
2018

26. Precise U-Pb zircon ages and geochemistry of Jurassic granites, Ellsworth-Whitmore terrane, central Antarctica

Author

Craddock, John P., Schmitz, Mark D., Crowley, James L., Larocque, Jeremiah, Pankhurst, Robert J., Juda, Natalie, Konstantinou, Alexandros, Storey, Bryan, Craddock, John P., Schmitz, Mark D., Crowley, James L., Larocque, Jeremiah, Pankhurst, Robert J., Juda, Natalie, Konstantinou, Alexandros, and Storey, Bryan

Abstract

The Ellsworth-Whitmore Mountain terrane of central Antarctica was part of the early Paleozoic amalgamation of Gondwana, including a 13,000 m section of Cambrian–Permian sediments in the Ellsworth Mountains deposited on Grenville-age crust. The Jurassic breakup of Gondwana involved a regional, bimodal magmatic event during which the Ellsworth-Whitmore terrane was intruded by intraplate granites before translation of the terrane to its present location in central Antarctica. Five widely separated granitic plutons in the Ellsworth-Whitmore terrane were analyzed for their whole-rock geochemistry (X-ray fluorescence), Sr, Nd, and Pb isotopic compositions, and U-Pb zircon ages to investigate the origins of the terrane magmas and their relationships to mafic magmatism of the 183 Ma Karoo-Ferrar large igneous province (LIP). We report high-precision (±0.1 m.y.) isotope dilution–thermal ionization mass spectrometry (ID-TIMS) U-Pb zircon ages from granitic rocks from the Whitmore Mountains (208.0 Ma), Nash Hills (177.4–177.3 Ma), Linck Nunatak (175.3 Ma), Pagano Nunatak (174.8 Ma), and the Pirrit Hills (174.3–173.9 Ma), and U-Pb sensitive high-resolution ion microprobe (SHRIMP) ages from the Whitmore Mountains (200 ± 5 Ma), Linck Nunatak (180 ± 4 Ma), Pagano Nunatak (174 ± 4 Ma), and the Pirrit Hills (168 ± 4 Ma). We then compared these results with existing K-Ar ages and Nd model ages, and used initial Sr, Nd, and Pb isotope ratios, combined with xenocrystic zircon U-Pb inheritance, to infer characteristics of the source(s) of the parent magmas. We conclude that the Jurassic plutons were not derived exclusively from crustal melts, but rather they are hybridized magmas composed of convecting mantle, subcontinental lithospheric mantle, and lower continental crustal contributions. The mantle contributions to the granites share isotopic similarities to the sources of other Jurassic LIP mafic magmas, including radiogenic 87Sr/86Sr (0.706–0.708), unradiogenic 143Nd/144Nd (εNd < –5

Published
2017

27. Zircon O- and Hf-isotope constraints on the genesis and tectonic significance of Permian magmatism in Patagonia

Author

Castillo, Paula, Fanning, C. Mark, Pankhurst, Robert J., Hervé, Francisco, Rapela, CarlosW., Castillo, Paula, Fanning, C. Mark, Pankhurst, Robert J., Hervé, Francisco, and Rapela, CarlosW.

Abstract

The genesis of Permian magmatism in southern South America is actively debated, particularly in relation to the origin of Patagonia. U–Pb zircon ages of c. 255 Ma for igneous rocks from the basement of Tierra del Fuego are the first evidence for southerly prolongation of this magmatism. Zircon in these rocks has εHft values <−1 and δ18O > 7.4‰, indicating recycling of Cambrian rocks. Permian granites in the north of the North Patagonian Massif record mantle-like δ18O magmatic input at c. 280 and 255 Ma, but reworking of upper crust between these two events, paralleling the recognized deformational history. In northwestern Patagonia, Early Permian granitic rocks have zircon with εHft values ranging from +0.1 to −7.2, and δ18O > 6.2‰, suggesting continuity of the Permian magmatic belt along the western margin of South America farther north. Comparison with a sample from the Sierra de la Ventana suggests melting of similar crust on both sides of the Patagonia–South American hypothetical suture. These features, together with other geological considerations, are consistent with an autochthonous or parautochthonous origin of northern Patagonia and connection between southern Patagonia and the Antarctic Peninsula in late Palaeozoic time. Supplementary material: U–Pb SHRIMP, O and Hf analytical data are available at https://doi.org/10.6084/m9.figshare.c.3768710

Published
2017

28. Early Jurassic magmatism on the Antarctic Peninsula and potential correlation with the Subcordilleran plutonic belt of Patagonia

Author

Riley, Teal R., Flowerdew, Michael J., Pankhurst, Robert J., Curtis, Mike L., Millar, Ian L., Fanning, C. Mark, Whitehouse, Martin J., Riley, Teal R., Flowerdew, Michael J., Pankhurst, Robert J., Curtis, Mike L., Millar, Ian L., Fanning, C. Mark, and Whitehouse, Martin J.

Abstract

Early Jurassic silicic volcanic rocks of the Chon Aike Province (V1: 187 – 182 Ma) are recognized from many localities in the southern Antarctic Peninsula and NE Patagonia and are essentially coeval with the extensive Karoo (182 Ma) and Ferrar (183 Ma) large igneous provinces of pre-breakup Gondwana. Until recently, plutonic rocks of this age were considered either rare in or absent from the Antarctic Peninsula batholith, which was thought to have been mainly constructed during the Middle Jurassic and the mid-Cretaceous. New U–Pb zircon geochronology from the Antarctic Peninsula and recently published U–Pb ages from elsewhere in the Peninsula and Patagonia are used to demonstrate the more widespread nature of Early Jurassic plutonism. Eight samples are dated here from the central and southern Antarctic Peninsula. They are all moderately to strongly foliated granitoids (tonalite, granite, granodiorite) and locally represent the crystalline basement. They yield ages in the range 188 – 181 Ma, which overlap with published ages of 185 – 180 Ma from granitoids from elsewhere on the Antarctic Peninsula and from the Subcordilleran plutonic belt of Patagonia (185 – 181 Ma). Whereas Early Jurassic plutons of the Subcordilleran plutonic belt of Patagonia are directly related to subduction processes along the proto-Pacific margin of Gondwana, coeval volcanic rocks of the Chon Aike Province are interpreted to be directly associated with extension and plume activity during the initial stages of Gondwana breakup. This indicates that subduction was continuing when Chon Aike Province volcanism started. The Early Jurassic plutonism on the Antarctic Peninsula is transitional between subduction-related and breakup-related magmatism.

Published
2017

29. Ultramafic rocks in the North Patagonian Andes: is their emplacement associated with the Neogene tectonics of the Liquine-Ofqui Fault Zone?

Author

Hervé, Francisco, Fuentes, F., Calderón, Mauricio, Fanning, Christopher Mark, Quezada, Paulo, Pankhurst, Robert J, Rapela, Carlos W, Hervé, Francisco, Fuentes, F., Calderón, Mauricio, Fanning, Christopher Mark, Quezada, Paulo, Pankhurst, Robert J, and Rapela, Carlos W

Abstract

Serpentinites and fresh or partially serpentinized harzburgite crop out in the western slope of the North Patagonian Andes of continental Chiloe (41 degrees 44'-42 degrees 12'S). These rocks are spatially associated with low-grade metamorphic rocks containing Cenozoic detrital zircons. The metamorphic rocks, together with Devonian metasediments, have been mapped previously as Late Paleozoic-Triassic metamorfic complex, an age no longer tenable for at least part of the complex. Transpressional tectonic emplacement of the ultramafic body or bodies is thought to have been related to activity on the Liquine-Ofqui Fault Zone, following a late Oligocene-Early Miocene extensional phase in the forearc region of the present Andes. This fault zone occurs immediately east of the outcrops of the ultramafic rocks and has been interpreted previously as generating a hemi-flower or flower structure.

Published
2017

30. Early Jurassic magmatism on the Antarctic Peninsula and potential correlation with the Subcordilleran plutonic belt of Patagonia

Author

Riley, Teal R, Flowerdew, Michael J., Pankhurst, Robert J, Curtis, Mike L, Millar, Ian L., Fanning, Christopher Mark, Whitehouse, M.J., Riley, Teal R, Flowerdew, Michael J., Pankhurst, Robert J, Curtis, Mike L, Millar, Ian L., Fanning, Christopher Mark, and Whitehouse, M.J.

Abstract

Early Jurassic silicic volcanic rocks of the Chon Aike Province (V1: 187 - 182 Ma) are recognized from many localities in the southern Antarctic Peninsula and NE Patagonia and are essentially coeval with the extensive Karoo (182 Ma) and Ferrar (183 Ma) large igneous provinces of pre-breakup Gondwana. Until recently, plutonic rocks of this age were considered either rare in or absent from the Antarctic Peninsula batholith, which was thought to have been mainly constructed during the Middle Jurassic and the mid-Cretaceous. New U-Pb zircon geochronology from the Antarctic Peninsula and recently published U-Pb ages from elsewhere in the Peninsula and Patagonia are used to demonstrate the more widespread nature of Early Jurassic plutonism. Eight samples are dated here from the central and southern Antarctic Peninsula. They are all moderately to strongly foliated granitoids (tonalite, granite, granodiorite) and locally represent the crystalline basement. They yield ages in the range 188 - 181 Ma, which overlap with published ages of 185 - 180 Ma from granitoids from elsewhere on the Antarctic Peninsula and from the Subcordilleran plutonic belt of Patagonia (185 - 181 Ma). Whereas Early Jurassic plutons of the Subcordilleran plutonic belt of Patagonia are directly related to subduction processes along the proto-Pacific margin of Gondwana, coeval volcanic rocks of the Chon Aike Province are interpreted to be directly associated with extension and plume activity during the initial stages of Gondwana breakup. This indicates that subduction was continuing when Chon Aike Province volcanism started. The Early Jurassic plutonism on the Antarctic Peninsula is transitional between subduction-related and breakup-related magmatism.

Published
2017

33. The continental assembly of SW Gondwana (Ediacaran to Cambrian): a synthesis

Author

Casquet, César, Rapela, Carlos W., Pankhurst, Robert J., Baldo, Edgardo G., Galindo, Carmen, Dahlquist, J., Verdecchia, Sebastián O., Murra, J. A., and Fanning, M.

Abstract

SW Gondwana resulted from complex interplay between continental amalgamation and dispersal between ~ 650 and 490 Ma. The main cratons involved were Laurentia, Amazonia– MARA (Proterozoic Maz–Arequipa–Rio Apa, Casquet et al., 2012), Kalahari, Rio de la Plata (RPC), Congo and East Antarctica (Mawson block). Several collisional orogenic belts resulted, notably the East Africa–Antarctica, Brasiliano–Panafrican, Pampean–Saldania, and Ross– Delamerian orogens. East-Antarctica broke away from the western margin of Laurentia in Rodinia. After a long drift and counter-clockwise rotation (Dalziel, 2013) it collided with Congo and Kalahari to produce the southern part of the left-lateral transpressional East Africa–Antarctica orogen between 580 and 550 Ma, completing the amalgamation of East Gondwana. The Trans-Antarctic margin became an active one in the Ediacaran and subduction of the Pacific Ocean lithosphere occurred throughout the Paleozoic, forming a tract of the Terra Australis orogen. NW–SE directed compression in Late Cryogenian and Early Ediacaran times promoted closure of the Adamastor Ocean, resulting in the left-lateral transpressional Brasiliano–Pan African orogeny between 650 and 570 Ma. The Pampean orogenic belt to the west of the RPC resulted from right-lateral collision between Laurentia and its eastern extension MARA on the one hand and Kalahari–RPC on the other. Ocean opening started at ~ 630 Ma and subduction and further collision took place between 540 and 520 Ma, coeval with the northward drift of Laurentia (~ 540 Ma) away from MARA and the consequent formation of the proto-Andean margin of Gondwana. The margins of the intervening Puncoviscana ocean were covered by Laurentia-derived siliciclastic sediments and carbonates on the MARA side between 630 and ~ 540 Ma (Rapela et al, 2014; this symposium), and by the marine siliciclastic Puncoviscana Formation on the other. The latter formation, deposited between a 570 and ~530 Ma, received input from large alluvial fans descending from juvenile Mesoproterozoic and Neproterozoic sources (new Hf isotope evidence) largely located in the southern East Africa–Antarctica orogen. The Pampean orogen extended into the Saldania–Gariep orogen of southern South Africa (545–520 Ma) and was apparently discordant to the earlier Brasiliano–Pan African orogen. In late-Early to late Cambrian times the Pampean–Saldania realm evolved into a passive margin with siliciclastic platform sedimentation. The Pampean-Saldania realm was separated from the active Trans-Antarctic margin of East Antarctica by an inferred transform fault in Ediacaran to Cambrian times. Regional NW–SW shortening in the Ediacaran became N–S directed in the Cambrian, suggesting a major plate reorganization at this time.

Published
2015

34. Identifying Laurentian and SW Gondwana sources in the Neoproterozoic to Early Paleozoic metasedimentary rocks of the Sierras Pampeanas: Paleogeographic and tectonic implications

Author

Rapela, Carlos W., Verdecchia, Sebastian O., Casquet, Cesar, Pankhurst, Robert J., Baldo, Edgardo G., Galindo, Carmen, Murra, Juan A., Dahlquist, Juan A., Fanning, C. Mark, Rapela, Carlos W., Verdecchia, Sebastian O., Casquet, Cesar, Pankhurst, Robert J., Baldo, Edgardo G., Galindo, Carmen, Murra, Juan A., Dahlquist, Juan A., and Fanning, C. Mark

Abstract

The provenance of Neoproterozoic to Early Paleozoic sedimentary rocks in the Sierras Pampeanas has been established using U–Pb SHRIMP age determination of detrital zircons in twelve metasedimentary samples, with supplementary Hf and O isotope analyses of selected samples. The detrital zircon age patterns show that the western and eastern sectors of the Sierras Pampeanas are derived from different sources, and were juxtaposed during the Early Cambrian ‘Pampean’ collision orogeny, thus defining initiation of the supercontinent stage of southwestern Gondwana. The Western Sierras Pampeanas (WSP), which extend northwards to the southern Puna (Antofalla) and the Arequipa Massif (Peru), constitute a single large continental basement of Paleoproterozoic age — the MARA block — that was reworked during the Grenvillian orogeny. The MARA block probably extends eastwards to include the Río Apa block (southern Brazil), but in this case without a Mesoproterozoic overprint. Detrital zircons from the WSP and Antofalla yield age peaks between 1330 and 1030 Ma, remarkably similar to the range of ages in the Grenville province of eastern Laurentia. The WSP Neoproterozoic sedimentary cover to this basement shows the same 1330–1030 component, but also includes important 1430–1380 Ma zircons whose juvenile Hf and O isotopic signatures strongly suggest derivation from the Grenville and the Southern Granite–Rhyolite provinces of eastern Laurentia. In contrast the Eastern Sierras Pampeanas metasedimentary rocks have a typically bimodal detrital zircon pattern with peaks at ca. 1000 and 600 Ma, which respectively indicate sources in the Natal–Namaqua belt and the East African orogen and/or the Dom Feliciano belt of SE Brazil and Uruguay. Sedimentary rocks in the Eastern Sierras Pampeanas and Patagonia deposited during the Late Early Cambrian–Early Ordovician interval, after the Pampean orogeny, have detrital patterns common to many sectors along the Terra Australis orogen, reflecting increasi

Published
2016

35. Isotope (Sr, C) and U–Pb SHRIMP zircon geochronology of marble-bearing sedimentary series in the Eastern Sierras Pampeanas, Argentina. Constraining the SW Gondwana margin in Ediacaran to early Cambrian times

Author

Secretaría de Ciencia y Técnica de la Nación (Argentina), Fondo para la Investigación Científica y Tecnológica (Argentina), Consejo Nacional de Investigaciones Científicas y Técnicas (Argentina), Ministerio de Ciencia e Innovación (España), Universidad Complutense de Madrid, Banco Santander, Murra, J. A., Casquet, César, Locati, Francisco, Galindo, Carmen, Baldo, Edgardo G., Pankhurst, Robert J., Rapela, Carlos W., Secretaría de Ciencia y Técnica de la Nación (Argentina), Fondo para la Investigación Científica y Tecnológica (Argentina), Consejo Nacional de Investigaciones Científicas y Técnicas (Argentina), Ministerio de Ciencia e Innovación (España), Universidad Complutense de Madrid, Banco Santander, Murra, J. A., Casquet, César, Locati, Francisco, Galindo, Carmen, Baldo, Edgardo G., Pankhurst, Robert J., and Rapela, Carlos W.

Abstract

The Sierras de Córdoba Metasedimentary Series consists of marbles and metasiliciclastic rocks of Ediacaran to early Cambrian age (ca. 630 and 540 Ma) that underwent high-grade metamorphism during the collisional Pampean orogeny in the early Cambrian. The ages of the marbles were determined from the Sr-isotope composition (blind dating) of screened samples of almost pure calcite marble and were further constrained with C- and O-isotope data and U–Pb SHRIMP detrital zircon ages of an interbedded paragneiss. Two groups of samples are recognised with Sr-isotope composition ca. 0.7075 and 0.7085 that are considered stratigraphically significant. The first is inferred early Ediacaran, the second late Ediacaran to early Cambrian. The Sierras de Córdoba Metasedimentary Series is correlated for the first time with marble-bearing metasedimentary series in several sierras to the west and north of Sierras de Córdoba (e.g., the Difunta Correa Sedimentary Sequence and the Ancaján Series), implying that all were probably parts of an originally extensive sedimentary cover. These series bear evidence of sedimentary sources in the Mesoproterozoic (and Paleoproterozoic) basement of the Western Sierras Pampeanas (part of the large MARA continental block) and farther west (Laurentia?). In terms of the age of limestones/marbles and detrital zircon patterns, the Sierras de Córdoba Metasedimentary Series differs strongly from the older section of late Ediacaran to early Cambrian Puncoviscana Formation of northwestern Argentina, which mostly outcrops in northern Sierra Chica and Sierra Norte, with sedimentary input from western Gondwana sources. The Sierras de Córdoba Metasedimentary Series and the Puncoviscana Formation were probably juxtaposed during the Pampean orogeny along a complex suture zone that was further folded and/or imbricated at mid-crustal depths. The peak of metamorphism was attained at 527 ± 2 Ma. According to the evidence found here most of the Sierras Pampeanas to the we

Published
2016

36. Mafic rocks of the Ordovician Famatinian magmatic arc (NW Argentina): New insights into the mantle contribution

Author

Ministerio de Ciencia, Tecnología e Innovación Productiva (Argentina), Ministerio de Economía y Competitividad (España), Alasino, Pablo H., Casquet, César, Pankhurst, Robert J., Rapela, Carlos W., Dahlquist, J., Galindo, Carmen, Larrovere, M. A., Recio, Clemente, Paterson, S. R., Colombo, F., Baldo, Edgardo G., Ministerio de Ciencia, Tecnología e Innovación Productiva (Argentina), Ministerio de Economía y Competitividad (España), Alasino, Pablo H., Casquet, César, Pankhurst, Robert J., Rapela, Carlos W., Dahlquist, J., Galindo, Carmen, Larrovere, M. A., Recio, Clemente, Paterson, S. R., Colombo, F., and Baldo, Edgardo G.

Abstract

We studied the petrogenesis of mafic igneous rocks in the Famatinian arc in the western Sierra Famatina (NW Argentina), an Early Ordovician middle-crustal section in the proto-Andean margin of Gondwana. Mafic rock types consist of amphibolite, metagabbro, and gabbro, as well as pod- and dike-like bodies of gabbro to diorite composition. Field relations together with geochemical and isotopic data for the mafic rocks of the western Sierra de Famatina (at 29°S) define two contrasting suites, which can be correlated with similar assemblages noted in other parts of the orogen. Amphibolite, metagabbro, and gabbro bodies are mostly the oldest intrusive rocks (older than 480 Ma), with the host tonalite and post-tonalite mafic dikes being slightly younger. The older mafic suite is tholeiitic to calc-alkaline and isotopically evolved, except for most of the amphibolite samples. The younger suite is calc-alkaline, typically displaying subduction-related geochemical signatures, and it is isotopically more juvenile. Whole-rock chemical composition and isotopic analyses are compatible with a progressive mixing of different isotopic reservoirs. Pyroxenite (±garnet) was likely the dominant source of the older gabbroic magmas, whereas peridotite dominated in the source of the younger suite, implying that the mafic magma experienced a progressive shift toward more juvenile compositions though time (over 20 m.y.). Pyroxenite-derived melts could have been generated by lithospheric foundering followed by upwelling of primitive melts by adiabatic decompression of mantle wedge peridotite.

Published
2016

37. Identifying Laurentian and SW Gondwana sources in the Neoproterozoic to Early Paleozoic metasedimentary rocks of the Sierras Pampeanas: Paleogeographic and tectonic implications

Author

Consejo Nacional de Investigaciones Científicas y Técnicas (Argentina), Fondo para la Investigación Científica y Tecnológica (Argentina), Ministerio de Economía y Competitividad (España), Universidad Complutense de Madrid, Banco Santander, Rapela, Carlos W., Verdecchia, Sebastián O., Casquet, César, Pankhurst, Robert J., Baldo, Edgardo G., Galindo, Carmen, Murra, J. A., Dahlquist, J., Fanning, M., Consejo Nacional de Investigaciones Científicas y Técnicas (Argentina), Fondo para la Investigación Científica y Tecnológica (Argentina), Ministerio de Economía y Competitividad (España), Universidad Complutense de Madrid, Banco Santander, Rapela, Carlos W., Verdecchia, Sebastián O., Casquet, César, Pankhurst, Robert J., Baldo, Edgardo G., Galindo, Carmen, Murra, J. A., Dahlquist, J., and Fanning, M.

Abstract

The provenance of Neoproterozoic to Early Paleozoic sedimentary rocks in the Sierras Pampeanas has been established using U–Pb SHRIMP age determination of detrital zircons in twelve metasedimentary samples, with supplementary Hf and O isotope analyses of selected samples. The detrital zircon age patterns show that the western and eastern sectors of the Sierras Pampeanas are derived from different sources, and were juxtaposed during the Early Cambrian ‘Pampean’ collision orogeny, thus defining initiation of the supercontinent stage of southwestern Gondwana. The Western Sierras Pampeanas (WSP), which extend northwards to the southern Puna (Antofalla) and the Arequipa Massif (Peru), constitute a single large continental basement of Paleoproterozoic age — the MARA block — that was reworked during the Grenvillian orogeny. The MARA block probably extends eastwards to include the Río Apa block (southern Brazil), but in this case without a Mesoproterozoic overprint. Detrital zircons from the WSP and Antofalla yield age peaks between 1330 and 1030 Ma, remarkably similar to the range of ages in the Grenville province of eastern Laurentia. The WSP Neoproterozoic sedimentary cover to this basement shows the same 1330–1030 component, but also includes important 1430–1380 Ma zircons whose juvenile Hf and O isotopic signatures strongly suggest derivation from the Grenville and the Southern Granite–Rhyolite provinces of eastern Laurentia. In contrast the Eastern Sierras Pampeanas metasedimentary rocks have a typically bimodal detrital zircon pattern with peaks at ca. 1000 and 600 Ma, which respectively indicate sources in the Natal–Namaqua belt and the East African orogen and/or the Dom Feliciano belt of SE Brazil and Uruguay. Sedimentary rocks in the Eastern Sierras Pampeanas and Patagonia deposited during the Late Early Cambrian–Early Ordovician interval, after the Pampean orogeny, have detrital patterns common to many sectors along the Terra Australis orogen, reflecting increasi

Published
2016

38. Comments on Bahlburg (2021), A Silurian-Devonian active margin in the proto- Andes –new data on an old conundrum: International Geology Review doi.org/10.1080/00206814.2021.2012719.

Author

Dahlquist, Juan A., Morales Cámera, Matías M., Alasino, Pablo H., Pankhurst, Robert J., Rapela, Carlos W., Moreno, Juan A., Baldo, Edgardo G., and Rocher, Sebastián

Subjects
GEOLOGY, MAGMATISM, DEVONIAN Period, SUBDUCTION
Abstract

We clarify some statements on our works included by Bahlburg (2021), which we think are confusing and misleading. Clarification is highly necessary to interpreting the evolution of the Devonian proto-Andean margin of Argentina and Chile, and in this work, we show that this clarification is appropriated and should be considered. [ABSTRACT FROM AUTHOR]

Published
2023
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41. Identifying Laurentian and SW Gondwana sources in the Neoproterozoic to Early Paleozoic metasedimentary rocks of the Sierras Pampeanas: Paleogeographic and tectonic implications

Author

Rapela, Carlos W., primary, Verdecchia, Sebastian O., additional, Casquet, Cesar, additional, Pankhurst, Robert J., additional, Baldo, Edgardo G., additional, Galindo, Carmen, additional, Murra, Juan A., additional, Dahlquist, Juan A., additional, and Fanning, C. Mark, additional

Published
2016
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42. Identifying Laurentian and SW Gondwana sources in the Neoproterozoic to Early Paleozoic metasedimentary rocks of the Sierras Pampeanas: paleogeographic and tectonic implications

Author

Rapela, Carlos W, Verdecchia, Sebastian O., Casquet, Cesar, Pankhurst, Robert J, Baldo, Edgardo, Galindo, Carmen, Murra, Juan A., Dahlquist, Juan A., Fanning, C. Mark, Rapela, Carlos W, Verdecchia, Sebastian O., Casquet, Cesar, Pankhurst, Robert J, Baldo, Edgardo, Galindo, Carmen, Murra, Juan A., Dahlquist, Juan A., and Fanning, C. Mark

Abstract

The provenance of Neoproterozoic to Early Paleozoic sedimentary rocks in the Sierras Pampeanas has been established using U–Pb SHRIMP age determination of detrital zircons in twelve metasedimentary samples, with supplementary Hf and O isotope analyses of selected samples. The detrital zircon age patterns show that the western and eastern sectors of the Sierras Pampeanas are derived from different sources, and were juxtaposed during the Early Cambrian ‘Pampean’ collision orogeny, thus defining initiation of the supercontinent stage of southwestern Gondwana. The Western Sierras Pampeanas (WSP), which extend northwards to the southern Puna (Antofalla) and the Arequipa Massif (Peru), constitute a single large continental basement of Paleoproterozoic age — the MARA block — that was reworked during the Grenvillian orogeny. The MARA block probably extends eastwards to include the Río Apa block (southern Brazil), but in this case without a Mesoproterozoic overprint. Detrital zircons from the WSP and Antofalla yield age peaks between 1330 and 1030 Ma, remarkably similar to the range of ages in the Grenville province of eastern Laurentia. The WSP Neoproterozoic sedimentary cover to this basement shows the same 1330–1030 component, but also includes important 1430–1380 Ma zircons whose juvenile Hf and O isotopic signatures strongly suggest derivation from the Grenville and the Southern Granite–Rhyolite provinces of eastern Laurentia. In contrast the Eastern Sierras Pampeanas metasedimentary rocks have a typically bimodal detrital zircon pattern with peaks at ca. 1000 and 600 Ma, which respectively indicate sources in the Natal–Namaqua belt and the East African orogen and/or the Dom Feliciano belt of SE Brazil and Uruguay. Sedimentary rocks in the Eastern Sierras Pampeanas and Patagonia deposited during the Late Early Cambrian–Early Ordovician interval, after the Pampean orogeny, have detrital patterns common to many sectors along the Terra Australis orogen, reflecting increasi

Published
2015

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