Postcollisional cooling history of the Eastern and Southern Alps and its linkage to Adria indentation

Heberer, Bianca; Reverman, Rebecca; Fellin, Maria Giuditta; Neubauer, Franz; Dunkl, İstván; Zattin, Massımılıano; Seward, Diane; Genser, Johann; Brack, Peter

doi:10.1007/s00531-016-1367-3

Cited by 29 publications

(53 citation statements)

References 114 publications

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“…Considering that additional back thrusting has been neglected in constructing our cross section, this should be considered as a minimum value, in agreement with the 46‐km value recorded in the western Southern Alps by Schmid et al (). Based on syntectonic sedimentation (Castellarin et al, ) and thermochronologic data (Heberer et al, ; Zattin et al, ), the preferred estimate for the onset of thrusting in the Southern Alps is about 14 Ma, thus yielding a long‐term shortening rate of about 3 mm/year, 2 times higher than the postglacial shortening rate. If assuming on the other hand that thrusting initiated as early as 21 Ma at the onset of Adria indentation (Pomella et al, ), then the long‐term mean shortening rate would be of 2 mm/year, which is still higher than the postglacial rate.…”

Section: Discussionmentioning

confidence: 99%

“…The remaining Neogene convergence has been essentially absorbed by eastward extrusion of the Eastern Alps (e.g., Frisch et al, ; Linzer et al, ; Ratschbacher et al, ). Crustal deformation in this sector of the Alps is probably older than that in the Southern Alps (Heberer et al, ) and accounts for 61–64 km of N‐S shortening (Linzer et al, ). The last source of Neogene shortening is represented by thrusting in the Northern Alps and accounts for about 10 km of N‐S shortening (Linzer et al, and references therein; Figure c).…”

Section: Discussionmentioning

confidence: 99%

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Fragmentation of the Adriatic Promontory: New Chronological Constraints From Neogene Shortening Rates Across the Southern Alps (NE Italy)

Moulin

Benedetti

2018

Tectonics

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The eastern Southern Alps are located at the northern tip of the Adria microplate, which imposes 2.0–2.5 mm/year of N‐S‐convergence relative to stable Eurasia. We map surface evidence of recent folding/faulting in this area from a 5‐m Digital Elevation Model (DEM). In the eastern part of the belt, observations reveal a 30‐km‐wide zone of active folding composed of at least five growing anticlines. The most recent ones warped the postglacial alluvial surface by <10 m. Combining these findings with published geological and geophysical data allows us to infer that active thrusting occurs along a single deeply rooted thrust, which accommodates the indentation of the Adriatic crust. Resolving the observed pattern of uplift on the inferred fault geometry indicates that NNE‐SSW shortening across the eastern Southern Alps has occurred at a rate of about 1.5 mm/year over the postglacial period. On the other hand, a balanced cross section for the eastern Southern Alps at the scale of the upper crust constrains a minimum of 43 km of finite shortening over the last 14 Ma, yielding a shortening rate of about 3 mm/year, which is 2 times higher than the postglacial shortening rate. This decrease in the shortening rate is associated to the Pleistocene activation of new thrusts that is compatible with a change in the direction of compression. The inferred local change in the kinematics of thrusting during the Pleistocene is consistent with a change from Nubia‐imposed to Adria‐imposed convergence indicating that the fragmentation of the Adriatic promontory could have occurred 1–2 Ma ago.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Fragmentation of the Adriatic Promontory: New Chronological Constraints From Neogene Shortening Rates Across the Southern Alps (NE Italy)

Moulin

Benedetti

2018

Tectonics

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“…(c) Vertical (filled circles) and horizontal (arrows) velocity field based on GPS time series indicating recent crustal motion and deformation in the ESA [ Grenerczy et al ., ; Weber et al ., ; Serpelloni et al ., ]. (d) Compilation of low‐temperature thermochronology data based on the distribution of apatite fission track ages (circles) [e.g., Luth and Willingshofer , and references therein; Fox et al ., , and references therein] and apatite (U–Th–Sm)/He ages (squares) [ Heberer et al ., ]. Solid black lines indicate the position of major faults.…”

Section: Study Regionmentioning

confidence: 99%

“…However, the scarcity of suitable lithology limits the applicability of low‐temperature thermochronometers for the Adriatic indenter, and data are mainly focused along major thrust systems (e.g., Valsugana thrust). There, latest Middle Miocene to Late Miocene exhumation and unroofing of ~ 4 km has led to the exposure of crystalline basement [ Zattin et al ., ; Heberer et al ., ]. In contrast, apatite fission track ages to the north and immediately to the west of the Valsugana thrust are Mesozoic [ Zattin et al ., ; Emmerich et al ., ; Heberer et al ., ], corroborating that overall exhumation throughout most of the ESA is minor [ Emmerich et al ., ; Zattin et al ., ] (Figure d).…”

Section: Study Regionmentioning

confidence: 99%

“…There, latest Middle Miocene to Late Miocene exhumation and unroofing of ~ 4 km has led to the exposure of crystalline basement [ Zattin et al ., ; Heberer et al ., ]. In contrast, apatite fission track ages to the north and immediately to the west of the Valsugana thrust are Mesozoic [ Zattin et al ., ; Emmerich et al ., ; Heberer et al ., ], corroborating that overall exhumation throughout most of the ESA is minor [ Emmerich et al ., ; Zattin et al ., ] (Figure d). Thin‐skinned tectonic shortening with fault‐propagation folding and fault‐bend folding prograded southward in the ESA, producing a pronounced relief, e.g., of 1200 m above the plain along the SE verging Bassano‐Valdobbiadene thrust [ Galadini et al ., ] (Figure ).…”

Section: Study Regionmentioning

confidence: 99%

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The topography of a continental indenter: The interplay between crustal deformation, erosion, and base level changes in the eastern Southern Alps

et al. 2017

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The topography of the eastern Southern Alps (ESA) reflects indenter tectonics causing crustal shortening, surface uplift, and erosional response. Fluvial drainages were perturbed by Pleistocene glaciations that locally excavated alpine valleys. The Late Miocene desiccation of the Mediterranean Sea and the uplift of the northern Molasse Basin led to significant base level changes in the far field of the ESA and the Eastern Alps (EA), respectively. Among this multitude of mechanisms, the processes that dominate the current topographic evolution of the ESA and the ESA‐EA drainage divide have not been identified. We demonstrate the expected topographic effects of each mechanism in a one‐dimensional model and compare them with observed channel metrics. We find that the normalized steepness index increases with uplift rate and declines from the indenter tip in the northwest to the foreland basin in the southeast. The number and amplitude of knickpoints and the distortion in longitudinal channel profiles similarly decrease toward the east. Changes in slope of χ‐transformed channel profiles coincide spatially with the Valsugana‐Fella fault linking crustal stacking and uplift induced by indenter tectonics with topographic evolution. Gradients in χ across the ESA‐EA drainage divide imply an ongoing, north directed shift of the Danube‐ESA watershed that is most likely driven by a base level rise in the northern Molasse basin. We conclude that the regional uplift pattern controls the geometry of ESA‐EA channels, while base level changes in the far field control the overall architecture of the orogen by drainage divide migration.

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Selected Type-Localities of Potassic Igneous Rocks from the Five Tectonic Settings

Müller

Groves

2018

Potassic Igneous Rocks and Associated Gold-Copper Mineralization

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Postcollisional cooling history of the Eastern and Southern Alps and its linkage to Adria indentation

Cited by 29 publications

References 114 publications

Fragmentation of the Adriatic Promontory: New Chronological Constraints From Neogene Shortening Rates Across the Southern Alps (NE Italy)

Fragmentation of the Adriatic Promontory: New Chronological Constraints From Neogene Shortening Rates Across the Southern Alps (NE Italy)

The topography of a continental indenter: The interplay between crustal deformation, erosion, and base level changes in the eastern Southern Alps

Selected Type-Localities of Potassic Igneous Rocks from the Five Tectonic Settings

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