Cenozoic Orogenic Evolution of the Southern Central Andes (32–36°S)

Giambiagi, Laura; Mescua, José; Bechis, Florencia; Hoke, Gregory D.; Suriano, Julieta; Spagnotto, Silvana; Moreiras, Stella Maris; Lossada, Ana Clara; Mazzitelli, Manuela Amelia; Dapoza, Rafael Toural; Folguera, Alicia; Mardónez, Diego; Pagano, Diego Sebastián

doi:10.1007/978-3-319-23060-3_4

Cited by 14 publications

(23 citation statements)

References 104 publications

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“…The orogenic profile consists of an onshore forearc basin (Central Valley), magmatic arc (Principal Cordillera), hybrid basement‐involved and thin‐skinned contractional belt (Malargüe fold‐thrust belt), and an eastern foreland basin partitioned by a single basement uplift (San Rafael block) and overprinted by a large igneous province (Payenia volcanic field). A maximum crustal thickness of 45–50 km is the result of Andean shortening and possible earlier thickening (Farías et al, ; Giambiagi et al, , Giambiagi, Mescua, et al, ; Mescua et al, ; Tassara & Echaurren, ). Estimates of shortening range from 15 to 45 km and involve a complex combination of detached thin‐skinned fold‐thrust and basement‐involved structures that commonly reactivate Mesozoic normal faults (Fuentes et al, ; Giambiagi et al, ; Manceda & Figueroa, ).…”

Section: Central To Southern Andes Transition (35°s)mentioning

confidence: 99%

“…This paper examines along‐strike (north‐south) and across‐strike (east‐west) variations in the Cretaceous‐Cenozoic geologic history of the central to southern Andes in an effort to emphasize potential temporal and spatial discrepancies in tectonic regimes for high‐shortening versus low‐shortening segments of the orogenic belt. Previous syntheses have focused on the magnitude and timing of deformation, episodic or cyclical changes in deformation and magmatism (including geochemical evolutionary trends), fluctuations in the geometry of the subducting slab, and the timing and mechanisms of surface uplift (e.g., Allmendinger et al, ; Barnes & Ehlers, ; Charrier et al, , ; DeCelles et al, ; Giambiagi, Mescua, et al, ; Garzione et al, ; Gianni et al, ; Haschke et al, , ; Kay et al, ; Kay & Coira, ; Oncken et al, ; Ramos et al, ; Ramos, , ; Ramos et al, ; Ramos & Kay, ; Rojas Vera et al, ; Trumbull et al, ). The goal here is not to replicate these valuable studies but to provide an integrated view of the Cretaceous‐Cenozoic records of (1) deformation (in terms of horizontal shortening, extension, or stasis), (2) magmatism (in terms of arc activity, arc cessation, or extension‐related within‐plate magmatism), and (3) sedimentary basin evolution (in terms of basin‐forming processes in foreland, hinterland, and forearc settings).…”

Section: Introductionmentioning

confidence: 99%

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Tectonic Regimes of the Central and Southern Andes: Responses to Variations in Plate Coupling During Subduction

2018

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Construction of the Andes has been governed largely by fluctuating contractional, neutral, and extensional tectonic regimes during differing degrees of mechanical coupling along the convergent plate boundary. These three contrasting regimes are likely regulated by geodynamic variations in absolute trenchward motion of South America and episodic regional shifts in the geometry of the subducting oceanic slab. Alternations among these three modes are revealed in syntheses of Mesozoic‐Cenozoic crustal deformation, basin evolution, and arc magmatism along orogen‐perpendicular transects across the central and southern Andes at 23°S, 35°S, and 43°S. Despite considerable along‐strike dissimilarities in the magnitude of deformation, a comparable tectonic regime typified the early Andean history, as defined by a transition from Late Jurassic‐Early Cretaceous postrift thermal subsidence to Late Cretaceous retroarc shortening. A key contradiction is expressed for the late middle Eocene to earliest Miocene, when neutral to extensional conditions affected retroarc to forearc regions, except in parts of the central Andes, which experienced retroarc shortening with only localized forearc extension. This mixed‐mode scenario during Paleogene time may reflect decoupling along the plate boundary (possibly during slab rollback within a retreating subduction system) in which widespread stasis or low‐magnitude extension dominated the southern Andes but was inhibited in the strongly shortened central Andes at 15–25°S where shallow subduction and/or high topography boosted plate coupling. Comparable temporal and spatial shifts in tectonic regime along the Andes and other convergent margins can be related to variable degrees of coupling during first‐order plate‐scale changes in convergence and second‐order regional cycles of slab shallowing and steepening.

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Section: Central To Southern Andes Transition (35°s)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Tectonic Regimes of the Central and Southern Andes: Responses to Variations in Plate Coupling During Subduction

2018

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“…Previous studies link the sedimentary infill of the Cacheuta Basin to the first stages of development of the main Andean range (Irigoyen, 1997;Irigoyen et al, 2000;Giambiagi and Ramos, 2003;Giambiagi et al, 2016). The onset of foreland sedimentation is coeval with a major phase of thrusting in the AFTB (Ramos et al, 1996a;Cegarra and Ramos, 1996;Irigoyen et al, 2000).…”

Section: Stratigraphic and Sedimentological Frameworkmentioning

confidence: 99%

“…Uplift of the Frontal Cordillera was expressed diachronously farther north by the topographic ranges of the Cordon del Tigre (32°S) and successively by the Cordon del Plata at 33°S around 10 Ma (Giambiagi and Ramos, 2003). The topographic expression of the Frontal Cordillera is presently limited to the northern part of the normal subduction segment, disappearing toward the south at approximately 34°S (Giambiagi et al, 2016). The Frontal Cordillera was uplifted during the eastward advance of the deformation front by east-verging thrust faults (Porras et al, 2016) connected to a décollement level in Jurassic evaporites (Fock Kunstmann, 2005).…”

Section: Accepted Manuscriptmentioning

confidence: 99%

“…Initial uplift of the Precordillera took place with further eastward migration of the flat-slab system and has been constrained at ~10 Ma (Walcek and Hoke, 2012), coeval with the continued uplifting of the Frontal Cordillera. The latter prevented the propagation of the thrust belt towards the Cacheuta foreland basin (Giambiagi et al, 2016), whose exposed stratigraphic successions remain to date only gently folded and affected by minor faulting in the study area.…”

Section: Accepted Manuscriptmentioning

confidence: 99%

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High-resolution compositional analysis of a fluvial-fan succession: The Miocene infill of the Cacheuta Basin (central Argentinian foreland)

Hunger

Ventra

Moscariello

et al. 2018

Sedimentary Geology

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Glacial and volcanic landforms in the upper catchment of Claro River, Central Chile (35.5°S): A Late Quaternary geomorphological case study

Mejías Osorio,

Cortés‐Aranda,

Salas

et al. 2024

Earth Surf Processes Landf

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The upper catchment of the Claro river is located within the Transitional Southern Volcanic Zone in the Maule Region of Chile (35.5°S), at the foothills of Manantial Pelado volcano, a Pleistocene stratovolcano whose morphology suggests the occurrence of important glacial processes in the area. The observed glacial landforms can be sequenced and associated with episodes of volcanic activity. Different units of volcanic and glacial origin were identified based on field observations, detailed mapping, and digital elevation model and satellite image analysis. The contact relations between them made it possible to discern four events that can be linked to Marine Isotope Stages 8, 6, 4‐2, and to the Neoglacial. We propose seven stages in the geomorphological evolution from the late Pleistocene to the late Holocene, where there is coexistence between volcanic and glacial episodes, such as the emplacement of the Manantial Pelado volcano overlying the Abanico and Cola de Zorro formations; a subsequent debris avalanche; the enlargement of the Del Indio valley during the Penultimate Glaciation; the construction of Cerro Redondo (a minor eruptive center at the head of Del Indio valley); ongoing fluvial incision; and Neoglacial advances. The relative chronology proposed in this work contributes to clarifying the Pleistocene–Holocene geomorphological history in this catchment and to further understand the interplay between volcanic and glacial processes in the central Chilean Andes during the Quaternary.

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Cenozoic Orogenic Evolution of the Southern Central Andes (32–36°S)

Cited by 14 publications

References 104 publications

Tectonic Regimes of the Central and Southern Andes: Responses to Variations in Plate Coupling During Subduction

Tectonic Regimes of the Central and Southern Andes: Responses to Variations in Plate Coupling During Subduction

High-resolution compositional analysis of a fluvial-fan succession: The Miocene infill of the Cacheuta Basin (central Argentinian foreland)

Glacial and volcanic landforms in the upper catchment of Claro River, Central Chile (35.5°S): A Late Quaternary geomorphological case study

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