Moho depth across the Trans-European Suture Zone from P-and S-receiver functions

The Mohorovicic discontinuity, Moho for short, which marks the boundary between crust and mantle, is the main first-order structure within the lithosphere. Geodynamics and tectonic evolution determine its depth level and properties. Here, we present a map of the Moho in central Europe across the Teisseyre-Tornquist Zone, a region for which a number of previous studies are available. Our results are based on homogeneous and consistent processing of P- and S-receiver functions for the largest passive seismological data set in this region yet, consisting of more than 40 000 receiver functions from almost 500 station. Besides, we also provide new results for the crustal Vp/Vs ratio for the whole area. Our results are in good agreement with previous, more localized receiver function studies, as well as with the interpretation of seismic profiles, while at the same time resolving a higher level of detail than previous maps covering the area, for example regarding the Eifel Plume region, Rhine Graben and northern Alps. The close correspondence with the seismic data regarding crustal structure also increases confidence in use of the data in crustal corrections and the imaging of deeper structure, for which no independent seismic information is available. In addition to the pronounced, stepwise transition from crustal thicknesses of 30km in Phanerozoic Europe to more than 45 beneath the East European Craton, we can distinguish other terrane boundaries based on Moho depth as well as average crustal Vp/Vsratio and Moho phase amplitudes. The terranes with distinct crustal properties span a wide range of ages, from Palaeoproterozoic in Lithuania to Cenozoic in the Alps, reflecting the complex tectonic history of Europe. Crustal thickness and properties in the study area are also markedly influenced by tectonic overprinting, for example the formation of the Central European Basin System, and the European Cenozoic Rift System. In the areas affected by Cenozoic rifting and volcanism, thinning of the crust corresponds to lithospheric updoming reported in recent surface wave and S-receiver function studies, as expected for thermally induced deformation. The same correlation applies for crustal thickening, not only across the Trans-European Suture Zone, but also within the southern part of the Bohemian Massif. A high Poisson’s ratio of 0.27 is obtained for the craton, which is consistent with a thick mafic lower crust. In contrast, we typically find Poisson’s ratios around 0.25 for Phanerozoic Europe outside of deep sedimentary basins. Mapping of the thickness of the shallowest crustal layer, that is low-velocity sediments or weathered rock, indicates values in excess of 6km for the most pronounced basins in the study area, while thicknesses of less than 4km are found within the craton, central Germany and most of the Czech Republic.Peer reviewe

Illite and chlorite cementation of siliciclastic sandstones influenced by clay grain cutans

The distribution and amount of clay rim cements are different for Permian Rotliegend and Lower Triassic Bunter sandstones in the Southern Permian and German Triassic Basins, respectively. Both are similar fluvial-aeolian deposits in hot-arid endorheic basins. In both Permian and Triassic sandstones clay grain cutans can be present, but clay rim cement is often lacking or rare in Bunter sandstones. At first sight it would appear that the presence of cutans is thus not relevant for the development of clay cementation. However, at closer inspection, it appears that authigenic clay is indeed present in both cases. In Rotliegend sandstones, the authigenic clay mainly developed as rims around the clay grain cutans, which are often thin and well microlaminated with few intra-micropores and composed of platy particles. The clay crystals in the rim decrease the pore interconnectivity and lower permeability significantly. In Bunter sandstones, most of the authigenic clay developed within the cutans. These cutans are less well microlaminated, have ample micropores, and are composed of more equant-shaped particles. The latter looser structure facilitated clay authigenesis within the cutans and their micropores. This often led to exfoliation of the cutan laminae and expansion of the entire cutan. These expanded cutans also lower pore connectivity. The presence and thickness of clay rim cement on top of cutans and grains is thus not correlated with the thickness of the cutans but with the texture of the cutans. The latter determined where authigenic clays precipitated and the thickness of cutans is partly the result of clay authigenesis within the cutans. This demonstrates that the composition and the texture of sedimentary components constrained and controlled burial diagenesis

3-D flexural modelling of the Silurian Baltic Basin.

The Baltic Basin (BB) is situated on the western part of the East European Craton (EEC). It was established initially as a passive margin basin in response to the breaking apart of the Rodinia megacontinent during the Latest Precambrian-Early Cambrian times. Thereafter, it has been suggested that the Late Ordovician-Silurian basin subsidence was generated by foreland bending of the western margin of the EEC as a result of the Caledonian convergence and collision of continental plates, namely Baltica, Laurentia, and Eastern Avalonia. This is based on the regional basin architecture, which indicates accelerating subsidence, rapid deepening of the basin, and significant thickening of the sedimentary succession towards the Tornquist-Teisseyre Zone (TTZ), along the southwestern margin of the EEC, during the Silurian. However, the very broad extent of the Silurian BB is not obviously explicable by a model of simple foreland flexure. This problem has been investigated by quantitative modelling of Caledonian foreland flexure, east of the TTZ, using a 3-D finite difference technique. The results are interpreted in terms of their implications for the rheology of the EEC and the geometry and temporal evolution of Caledonian orogenic loading. Assuming higher values of effective elastic thickness (EET) for the EEC than for Caledonian lithosphere, the model results demonstrate that the evolution of the BB cannot be explained by the effects of orogenic loads lying only on the west of the present Caledonian Deformation Front (CDF). Furthermore, the inferred shape of the BB deflection is not easily reproduced, even allowing lateral changes of EEC lithosphere EET. Rather, additional loads east of the CDF (and TTZ) were necessary, in order to replicate the shape and amplitude of the BB as a flexural basin. These are tentatively interpreted to be dynamic loads related to mantle flow above an eastward dipping Silurian subduction zone. © 2002 Published by Elsevier Science B.V