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Paleogeographic implications of a multi-parameter Paleogene provenance dataset (Transylvanian Basin, Romania)
Detrital zircon geochronology and heavy mineral analysis as complementary provenance tools in the presence of extensive weathering, reworking and recycling: the Neogene of the southern North Sea Basin
Life-cycle analysis of coesite-bearing garnet
Terrestrial kaolin deposits trapped in Miocene karstic sinkholes on planation surface remnants, Transdanubian Range, Pannonian Basin (Hungary)
Estimation of radiation damage in titanites using Raman spectroscopy
Diamond and coesite inclusions in detrital garnet of the Saxonian Erzgebirge, Germany
Thermal evolution in the exhumed basement of a stratovolcano: case study of the Miocene Mátra Volcano, Pannonian Basin
Peneplain formation in southern Tibet predates the India-Asia collision and plateau uplift: REPLY
Petrological, Geochemical, and Statistical Analysis of Eocene–Oligocene Sandstones of the Western Thrace Basin, Greece and Bulgaria
Products and timing of diagenetic processes in Upper Rotliegend sandstones from Bebertal (North German Basin, Parchim Formation, Flechtingen High, Germany)
Peneplain formation in southern Tibet predates the India-Asia collision and plateau uplift
Alpine tectonics north of the Alps
Abstract The Cenozoic tectonic evolution of Central Europe was governed over long periods of time by far-field stresses resulting from continent collision in the Alps (which is still ongoing) ridge push in the Atlantic Ocean, and other sources. Such far-field stresses interfered with more local stresses related to processes such as the rise of mantle plumes, leading to the Cenozoic volcanism of Central Europe, and glaciation. Alpine tectonics north of the Alps began with the effects, of Late Cretaceous_Early Palaeogene continent collision in the Pyrenees, on the European crust. During Tertiary times, the stress field was unstable and repeatedly changed both in terms of magnitude and orientation. Notably, an episode of ESE-WNW to east-west directed extension during the late Eocene to Oligocene created the European Cenozoic Rift System (Rhône-Bresse Graben, Upper Rhine Graben, Lower Rhine Basin, and others) which up to the present is tectonically the most active zone of Central Europe. Flexural basins formed in the southernmost part of the Alpine-Carpathian foreland. The Jura Mountains also form part of the Alpine foreland, although they could, from a tectonic point of view, also be regarded as part of the Alps. They represent the most external foreland fold-and-thrust belt of the Alps. Folding and thrusting in the Jura Mountains took place during the Middle Miocene to Pliocene, and the thrust front presently propagates northward into the Upper Rhine Graben. The Alpine tectonics of southern Germany may best be described in terms of reactivation of older inherited, mainly Variscan, basement structures. This is also the case for the central Leine Graben, the Harz Mountains and parts of the North German Basin. Because of the frequent reactivation of faults, the following sections include some remarks on pre-Alpine deformation and sedimentation history. The general episodes of Alpine deformation north of the Alps can be subdivided into three main phases: (1) the period of Late Cretaceous-Early Palaeogene inversion tectonics, when far-field effects of continent collision and the formation of the Pyrenees resulted in deformation extending as far north as the Danish North Sea, including the large-scale uplift of the Harz Mountains; (2) Eocene to Miocene extensional tectonics with the formation of large graben systems, for example the Upper Rhine Graben; and (3) the phase of tectonics related to the reorganization of the stress field during the Late Miocene, which coincides with the initiation of the ‘neotectonic period’ and the present-day stress field in Central Europe, which is characterized by SE-NW compression and NE-SW extension. The Neogene to recent evolution of northern Central Europe, including the North German Basin and the Polish Basin, which are parts of the Central European Basin System, was partly affected by glacial loading and unloading during the Pleistocene. Presently, these regions are areas of low seismicity (macroseis mic intensities III-IV EMS; Grünthal & Mayer-Rosa 1998 ). Major stresses acting within the North German Basin and the Polish Basin were induced by the North Atlantic ridge push forces (east-west, or NW-SE directed), the ongoing Alpine collision (north-south directed), and, from the late Pleistocene onwards, the post-glacial rebound of Fennoscandia (mainly vertical, but also with a horizontal, west-east directed component). Present-day maximum horizontal stresses within the North German Basin are generally directed NW-SE ( Rockel & Lempp 2003 ), but fan and bend towards the NNE, north of 52°N and east of 11°E, especially in the Polish Basin. The present-day stress field in the Central European Basin System is influenced by the decoupling of two crustal units ( Roth & Fleckenstein 2001 ), which are separated by Zechstein evaporites (the Pre Zechstein formations together with the older units are decoupled from the overlying Mesozoic and Cenozoic sediments). The general stress orientation, with NE-SW maximum horizontal stress, was regionally modified or disturbed ( Rockel & Lempp 2003 ). In areas of salt movement and the formation of salt pillows, salt walls and diapirs, the resultant local increase or decrease in salt thickness had a marked effect on stresses and tectonic structures (e.g. in the western Baltic Sea ( Hansen et al. 2005 ) and in the Gliickstadt Graben area ( Maystrenko et al. 2005 ). Major basement faults within the intracratonic Central European Basin System are orientated NW-SE, while minor faults trend NE-SW and NNE-SSW, and are clearly visible in shaded relief and satellite images ( Reicherter et al. 2005 ). The northern rim of the Central European Basin System is bounded by the Tornquist Zone, which consists of the Teisseyre-Tornquist Zone from Poland to Bornholm Island, and the Sorgenfrei-Tornquist Zone from southern Sweden to Denmark ( Fig. 19.1 ). Additionally, the drainage pattern and the distribution of lakes in northern Germany parallel the block boundaries and, hence, mark zones of present-day subsidence ( Mörner 1979 ; Stackebrandt 2004 ; Reicherter et al. 2005 ). A broad zone of subsidence extends from Hamburg to Berlin and onto Wroclaw (Poland) and is delineated by the depth to the base of the Rupelian Clay (Oligocene; Garetzky et al. 2001 ). This zone shows relatively minor faulting in the near-surface layers. The depocentre axes also had a NW-SE trend during the Mesozoic.
Abstract Flysch deposits are associated with the Outer Dinaride nappe front. They overlie Eocene platform carbonate to bathyal marl successions that subsequently cover Cretaceous platform carbonates of Apulia and the Dinaride nappes. Planktonic foraminifer biostratigraphy indicates Eocene age of flysch sedimentation. New calcareous nannofossil data reveal that several assemblages are present; besides the dominant Mid-Eocene species, Cretaceous, Paleocene, Oligocene and Miocene taxa were also identified throughout the entire flysch belt. Widespread occurrence of nannofossil species of zone NN4-6 indicates that flysch deposition lasted up to at least the Mid-Miocene. Ubiquitous occurrence of various pre-Miocene taxa demonstrates that extensive, possibly submarine, sediment recycling has occurred in the Cenozoic. As flysch remnants are typically sandwiched between thrust sheets, these new stratigraphic ages give a lower bracket on deformation age of the coastal range. The data provide a link between Cretaceous compression in the Bosnian Flysch and recent deformation in the Adriatic offshore area.