Surface cracks—geomorphological indicators for late Quaternary halotectonic movements in Northern Germany

Hardt, Jacob; Norden, Ben; Bauer, Klaus; Toelle, Ole; Krambach, Jenny

doi:10.1002/esp.5226

Cited by 10 publications

(16 citation statements)

References 73 publications

(151 reference statements)

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“…This study was intended primarily as a parameter study and was not aimed at reproducing any real-world situations. The deformation observed in the models is generally lower than measurements or estimates from field observations, which commonly indicate several tens of metres of displacement (cf., Sirocko et al 2002;Stackebrandt 2005Stackebrandt , 2016Müller and Obst 2008;Al Hseinat et al 2016;Hardt et al 2021). The discrepancy between models and field observations was already observed in a previous modelling study by Lang et al (2014).…”

Section: Towards More Realistic Modelsmentioning

confidence: 90%

“…Pleistocene or Holocene salt movements have been inferred for a number of salt structures in this area. However, it remains unresolved if Pleistocene and Holocene salt movements are the continuation of pre-Pleistocene processes controlled by the regional stress field or if ice-sheet loading triggered a reactivation (Sirocko et al 2008;Al Hseinat et al 2016;Hardt et al 2021).…”

Section: Introductionmentioning

confidence: 99%

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Deformation of salt structures by ice-sheet loading: insights into the controlling parameters from numerical modelling

Lang

Hampel

2023

Int J Earth Sci (Geol Rundsch)

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Subsurface salt flow is driven by differential loading, which is typically caused by tectonics or sedimentation. During glaciations, the weight of an ice sheet represents another source of differential loading. In salt-bearing basins affected by Pleistocene glaciations, such as the Central European Basin System, ice loading has been postulated as a trigger of young deformation at salt structures. Here, we present finite-element simulations (ABAQUS) with models based on a simplified 50-km long and 10-km-deep two-dimensional geological cross-section of a salt diapir subject to the load of a 300-m-thick ice sheet. The focus of our study is to evaluate the sensitivity of the model to material parameters, including linear and non-linear viscosity of the salt rocks and different elasticities. A spatially and temporarily variable pressure was applied to simulate ice loading. An ice advance towards the diapir causes lateral salt flow into the diapir and diapiric rise. Complete ice coverage leads to downward displacement of the diapir. After unloading, displacements are largely restored. The modelled displacements do not exceed few metres and are always larger in models with linear viscosity than in those with non-linear viscosity. Considering the low stresses caused by ice-sheet loading and the long time-scale, the application of linear viscosity seems appropriate. The elastic parameters also have a strong impact, with lower Young's moduli leading to larger deformation. The impact of both the viscosity and the elasticity highlights the importance of a careful parameter choice in numerical modelling, especially when aiming to replicate any real-world observations.

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Section: Towards More Realistic Modelsmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Deformation of salt structures by ice-sheet loading: insights into the controlling parameters from numerical modelling

Lang

Hampel

2023

Int J Earth Sci (Geol Rundsch)

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“…This may indicate a somehow distorted layering of the strata or just be related to a worse acoustic coupling due to higher thicknesses of younger sediments with low densities. From surface studies, Hardt et al (2021) interpret Quaternary landforms to result from the interaction of glacial tectonics and halo tectonics. Their location corresponds to the area where the deep fracture are assigned in the 3D seismic volume.…”

Section: Structural Informationmentioning

confidence: 99%

From pilot site knowledge via integrated reservoir characterization to utilization perspectives of a deep geothermal reservoir: 3D geological model at the research platform Groß Schönebeck in the Northeast German Basin

Norden

Bauer

Krawczyk

2022

Preprint

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The Groß Schönebeck site in the North German Basin serves as research platform for studying the geothermal potential of deeply buried Permian reservoir rocks and the technical feasibility to extract their geothermal heat. The structural setting of the site was investigated in more detail by studying a newly acquired 3D-seismic survey to improve the structural picture that was based on several old 2D seismic lines so far. The new data allows a revision of the geological interpretation of the site, enabling the set-up of a new reservoir model and providing base information for a possible further site development of the Permian and Permo-Carboniferous targets. The 3D seismic of Groß Schönebeck allows for the first time a consistent geological interpretation and model parameterization of the well-studied geothermal site. Main reflector horizons and the corresponding stratigraphic units were mapped and the structural pattern of the subsurface presented in the 8 km x 8 km x 4 km large seismic volume. While some fracture and fault patterns are visible in the upper Zechstein and post-Permian units, formerly hypothesized large offset faults are not present in the Rotliegend reservoir itself. However, a well-established graben-like structure at the top of the Zechstein succession is most likely related to broken anhydritic Zechstein stringers. Most reflectors above the salt show a rather undisturbed pattern. The main reservoir sandstone of the Dethlingen Formation (Rotliegend) was mapped and characterized. The base of the underlying Permo-Carboniferous volcanic rock sequence and hence its thickness could not be depicted reliably from the geophysical data. Based on the new seismic data and the available reconnaissance drilling, logging, and laboratory data of the Groß Schönebeck research site, the thickness and distribution of the sedimentary Rotliegend (with emphasis of the sandy reservoir section) and of the volcanic rock sequence was modelled and parameterized with petrophysical properties (i.e., total and effective porosity, fluid permeability, bulk density, thermal conductivity, thermal diffusivity, and specific heat capacity), providing a more realistic reservoir description. The data and interpretation constitute the basis for a better understanding of the dominating processes at the site and for future measures. Further site development could include a deepening of one well to give evidence on the volcanic rock sequence and consider deviated wells into favourable zones and the design of a fracture-dominated utilization approach.

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“…Information with regard to the geopark can be accessed via the park's website https://www.geopark-eiszeitland.de/ (last access: 28 July 2022). Boulders from the terminal moraine surface were among the first to be dated by means of surface exposure dating (SED) using cosmogenic nuclides (specifically 10 Be) in north-eastern Germany (Heine et al, 2009). Methodological advances in cosmogenic nuclide dating required a recalculation of these ages, which was conducted by , resulting in ages around 18-20 ka, indicating the retreat of the ice front from its G-LGM position at that time.…”

Section: Ihlowberge-sperlingsherberge (Terminal Moraines Of the Pomer...mentioning

confidence: 99%

“…The aim of this field trip was to demonstrate the exceptionally wellpreserved and textbook-like geomorphology and sedimentology of the glacial series (Glaziale Serie) of the Pomeranian (W 2 ) ice-marginal position in the Eberswalde-Chorin area, contrasting it with the challenging geomorphological and sedimentological record of the area assigned to the "vanishing" Frankfurt (W 1F ) ice-marginal position. Over the last years, several geomorphological and geochronological studies applying up-to-date methodology (Lüthgens et al, , 2010aLüthgens andBöse, 2011, 2012;Hardt et al, 2015Hardt et al, , 2021Heine et al, 2009;Brauer et al, 2005;Rinterknecht et al, 2006Rinterknecht et al, , 2012 in that broader ; data from Ehlers and Gibbard, 2004).…”

Section: Introductionmentioning

confidence: 99%

Ice dynamics in the SW sector of the Scandinavian Ice Sheet (SIS) – a fresh perspective from the classical area of the Weichselian glaciation in northern Brandenburg

Lüthgens

Hardt

2022

DEUQUA Spec. Pub.

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Abstract. The glacial landscape of northern Brandenburg, especially the Eberswalde–Chorin area, is one of the most important study areas of Quaternary research in northern Germany, not only with respect to its research history, but especially with regard to new mapping, sedimentological logging, and dating results using up-to-date methodologies. These new results have added an important puzzle-piece contributing to the development of a new concept of ice dynamics in the SW sector of the Scandinavian Ice Sheet (SIS) during Marine Isotope Stage 2 (MIS 2). After an introduction to the glacial geomorphology of the area, key sites visited during the field trip are explained, and the recent results are introduced and discussed.

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Surface cracks—geomorphological indicators for late Quaternary halotectonic movements in Northern Germany

Cited by 10 publications

References 73 publications

Deformation of salt structures by ice-sheet loading: insights into the controlling parameters from numerical modelling

Deformation of salt structures by ice-sheet loading: insights into the controlling parameters from numerical modelling

From pilot site knowledge via integrated reservoir characterization to utilization perspectives of a deep geothermal reservoir: 3D geological model at the research platform Groß Schönebeck in the Northeast German Basin

Ice dynamics in the SW sector of the Scandinavian Ice Sheet (SIS) – a fresh perspective from the classical area of the Weichselian glaciation in northern Brandenburg

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