Distribution, geometry, age and origin of overdeepened valleys and basins in the Alps and their foreland

Preusser, Frank; Reitner, Jürgen M.; Schlüchter, Christian

doi:10.1007/s00015-010-0044-y

Cited by 150 publications

(118 citation statements)

References 98 publications

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“…We tentatively argue for a tributary of the paleo-Salzach river draining Alpine basin further to the north (Donadel et al, 2014). The encountered coarse-grained facies is very different from the common facies of the Salzach Valley fill near the city of Salzburg mainly comprising lacustrine fines / mudstones (Kramer and Kröll, 1977;Brandecker, 1974;van Husen, 1980;Preusser et al, 2010).…”

Section: Quaternary Salzach Valley Basin Infillmentioning

confidence: 89%

A geological snapshot from the front of the Northern Calcareous Alps: Well Obermoos TH-1, Salzburg, Austria

Wessely¹,

Neubauer²,

Salcher³

et al. 2016

AJES

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The deep thermal well Obermoos TH-1 (total depth 2468 m, year 1990) was drilled within the Upper Cretaceous Salzburg-Reichenhall basin of the Northern Calcareous Alps at the southwestern edge of Salzburg city, Austria. The lithologic log shows c. 200 m thick Quaternary sediments of the glacially overdeepened Salzach Valley above bedrock. The Quaternary infill is underlain by c. 250 m thick, almost horizontally lying coarse clastics and marls, which belong to the Upper Cretaceous Salzburg-Reichenhall Gosau basin. From 456 m to 2468 m, a steeply dipping, more or less continuous succession from Cenomanian strata to Upper Triassic Hauptdolomit was encountered. This succession is considered being part of the Bajuvaric nappe of the central Northern Calcareous Alps, which is entirely overridden by units of the Tyrolic arc in the study area. The new data from the deep drilling provides (i) new information on depth and filling of the deeper parts of the Pleistocene valley and (ii) new insights into the complex structure of the Bajuvaric nappe. We also discuss a potential fault crossing the Salzburg-Reichenhall basin being part of the Cenozoic Innsbruck-Salzburg-Amstetten fault system. On a larger scale, the Tyrolic unit exposed in the southern margin of the Salzburg-Reichenhall basin and potentially overlying the borehole section must be the same as in the flat-laying Tyrolic nappe found in two deep drill holes, 15 km southeast and 18 km east of the City of Salzburg (Vigaun 1 and Vordersee 1).

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Section: Quaternary Salzach Valley Basin Infillmentioning

confidence: 89%

A geological snapshot from the front of the Northern Calcareous Alps: Well Obermoos TH-1, Salzburg, Austria

Wessely¹,

Neubauer²,

Salcher³

et al. 2016

AJES

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“…Such a bipartite valley fill is found in many glacially carved valleys (e.g. Brückl et al, 2010;Preusser et al, 2010).…”

Section: Bedrock Geometry and Valleyfill At Großer Ahornbodenmentioning

confidence: 90%

“…For example, the central Inn Valley in Tyrol was some 250 m higher at the end of the Middle Würmian some 30 ka ago and the river valley was two to three times wider than today . The Last Glacial Maximum (LGM) resulted in large-scale erosion of these former sediments, whereby the depth of this subglacial erosion is poorly known in most valleys of the Alps (Preusser et al, 2010). Subsequent to the LGM large quantities of clastic sediment were deposited during the meltdown of the ice masses .…”

Section: Introductionmentioning

confidence: 99%

Quaternary evolution of the inner Riss Valley, Tyrol (Austria) – an integrated sedimentological and geophysical case study

Mair¹,

Chwatal²,

Reimer³

et al. 2016

AJES

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We present the results of a study examining Quaternary sediments in the central and inner Riss Valley of the Karwendel Mountains, Tyrol. By using geological mapping, seismic and geoelectrical surveys, as well as shallow drilling and radiocarbon dating we investi gated the sedimentary evolution of this previously poorly studied area. At Großer Ahornboden, seismic data reveal a glacially carved bedrock surface, buried beneath up to 140 m of sediments. The lowest sediment sequence consists of consolidated sediments showing high seismic velocities (2750 m/s) and reaching a thickness of 115 m. The overlying uncompacted sequence yielded lower velocity values (500 to 1100 m/s) and is interpreted as Holocene valley fill, with sediment derived from Rissbach river, small talus screes and debris-flow fans from tributary creeks. Up to 10-m-thick deposits of a Holocene paleolake, dammed by a large Lateglacial terminal moraine ridge, are present at the northern rim of Großer Ahornboden. Radiocarbon dates constrain the duration of this lake to between 10.5-10.2 and 5.5-5.3 cal ka BP. Lacustrine sediments pinch out in the subsurface just below the small fan leading down from Tränkkarl. In the central Riss Valley over 100 m thick, consolidated sediments of a proglacial delta are exposed. This delta complex consists of bottomset silts and thick foreset gravel and is overlain by diamict forming poorly developed moraine ridges of Lateglacial origin.

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“…Thick layers of coarsegrained (gravel and sand) alluvial sediments fill the glacially overdeepened alpine valleys. Postglacial landslides are a consequence of pressure release after deglaciation (Preusser et al 2010). Particularly in narrow alpine valleys such as the presented upper Gurk Valley, these landslides create temporal barriers for the surface runoff.…”

Section: Introductionmentioning

confidence: 99%

“…In the resulting temporal lakes, lacustrine sedimentation takes place and leads to the development of fine-grained (silt and clay) layers. Changing conditions with sequences of alluvial and lacustrine sedimentation lead to a heterogenous internal structure of the sedimentary valley fill (Preusser et al 2010;Bleibinhaus and Hilberg 2012;Salcher et al 2012) with strong influences on the aquifer structure and the groundwater flow dynamics within the valley floor.…”

Section: Introductionmentioning

confidence: 99%

Interaction of various flow systems in small alpine catchments: conceptual model of the upper Gurk Valley aquifer, Carinthia, Austria

Hilberg

Riepler²

2016

Hydrogeol J

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Small alpine valleys usually show a heterogeneous hydraulic situation. Recurring landslides create temporal barriers for the surface runoff. As a result of these postglacial processes, temporal lakes form, and thus lacustrine finegrained sedimentation intercalates with alluvial coarsegrained layers. A sequence of alluvial sediments (confined and thus well protected aquifers) and lacustrine sediments (aquitards) is characteristic for such an environment. The hydrogeological situation of fractured hard-rock aquifers in the framing mountain ranges is characterized by superficially high hydraulic conductivities as the result of tectonic processes, deglaciation and postglacial weathering. Fracture permeability and high hydraulic gradients in small-scaled alpine catchments result in the interaction of various flow systems in various kinds of aquifers. Spatial restrictions and conflicts between the current land use and the requirements of drinkingwater protection represent a special challenge for water resource management in usually densely populated small alpine valleys. The presented case study describes hydrogeological investigations within the small alpine valley of the upper Gurktal (Upper Carinthia, Austria) and the adjacent H ö l l e n b e rg M a s s i f ( 1 , 7 7 2 m a b o v e s e a l e v e l ) . Hydrogeological mapping, drilling, and hydrochemical and stable isotope analyses of springs and groundwater were conducted to identify a sustainable drinking-water supply for approximately 1,500 inhabitants. The results contribute to a conceptual hydrogeological model with three interacting flow systems. The local and the intermediate flow systems are assigned to the catchment of the Höllenberg Massif, whereas the regional flow system refers to the bordering Gurktal Alps to the north and provides an appropriate drinking water reservoir.

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Distribution, geometry, age and origin of overdeepened valleys and basins in the Alps and their foreland

Cited by 150 publications

References 98 publications

A geological snapshot from the front of the Northern Calcareous Alps: Well Obermoos TH-1, Salzburg, Austria

A geological snapshot from the front of the Northern Calcareous Alps: Well Obermoos TH-1, Salzburg, Austria

Quaternary evolution of the inner Riss Valley, Tyrol (Austria) – an integrated sedimentological and geophysical case study

Interaction of various flow systems in small alpine catchments: conceptual model of the upper Gurk Valley aquifer, Carinthia, Austria

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