TY  - JOUR
A1  - Balling, Philipp
A1  - Maystrenko, Yuriy
A1  - Scheck-Wenderoth, Magdalena
T1  - The deep thermal field of the Glückstadt Graben
JF  - Environmental earth sciences
N2  - With this paper, we assess the present-day conductive thermal field of the Glueckstadt Graben in NW Germany that is characterized by large salt walls and diapirs structuring the graben fill. We use a finite element method to calculate the 3D steady-state conductive thermal field based on a lithosphere-scale 3D structural model that resolves the first-order structural characteristics of the graben and its underlying lithosphere. Model predictions are validated against measured temperatures in six deep wells. Our investigations show that the interaction of thickness distributions and thermal rock properties of the different geological layers is of major importance for the distribution of temperatures in the deep subsurface of the Glueckstadt Graben. However, the local temperatures may result from the superposed effects of different controlling factors. Especially, the upper sedimentary part of the model exhibits huge lateral temperature variations, which correlate spatially with the shape of the thermally highly conductive Permian salt layer. Variations in thickness and geometry of the salt cause two major effects, which provoke considerable lateral temperature variations for a given depth. (1) The "chimney effect" causes more efficient heat transport within salt diapirs. As a consequence positive thermal anomalies develop in the upper part and above salt structures, where the latter are covered by much less conductive sediments. In contrast, negative thermal anomalies are noticeable underneath salt structures. (2) The "thermal blanketing effect" is caused by thermally low conductive sediments that provoke the local storage of heat where these insulating sediments are present. The latter effect leads to both local and regional thermal anomalies. Locally, this translates to higher temperatures where salt margin synclines are filled with thick insulating clastic sediments. For the regional anomalies the cumulative insulating effects of the entire sediment fill results in a long-wavelength variation of temperatures in response to heat refraction effects caused by the contrast between insulating sediments and highly conductive crystalline crust. Finally, the longest wavelength of temperature variations is caused by the depth position of the isothermal lithosphere-asthenosphere boundary defining the regional variations of the overall geothermal gradient. We find that a conductive thermal model predicts observed temperatures reasonably well for five of the six available wells, whereas the steady-state conductive approach appears not to be valid for the sixth well.
KW  - Conductive thermal field
KW  - 3D thermal modelling
KW  - Zechstein salt
KW  - Lithosphereasthenosphere boundary
KW  - Schleswig-Holstein
KW  - Glueckstadtgraben
Y1  - 2013
U6  - https://doi.org/10.1007/s12665-013-2750-z
SN  - 1866-6280
SN  - 1866-6299
VL  - 70
IS  - 8
SP  - 3505
EP  - 3522
PB  - Springer
CY  - New York
ER  - 
TY  - JOUR
A1  - Spooner, Cameron
A1  - Scheck-Wenderoth, Magdalena
A1  - Götze, Hans-Jürgen
A1  - Ebbing, Jörg
A1  - Hetenyi, Gyoergy
T1  - Density distribution across the Alpine lithosphere constrained by 3-D gravity modelling and relation to seismicity and deformation
JF  - Solid earth
N2  - The Alpine orogen formed as a result of the collision between the Adriatic and European plates. Significant crustal heterogeneity exists within the region due to the long history of interplay between these plates, other continental and oceanic blocks in the region, and inherited crustal features from earlier orogenies. Deformation relating to the collision continues to the present day. Here, a seismically constrained, 3-D structural and density model of the lithosphere of the Alps and their respective forelands, derived from integrating numerous geoscientific datasets, was adjusted to match the observed gravity field. It is shown that the distribution of seismicity and deformation within the region correlates well to thickness and density changes within the crust, and that the present-day Adriatic crust is both thinner and denser (22.5 km, 2800 kg m(-3) ) than the European crust (27.5 km, 2750 kg m(-3)). Alpine crust derived from each respective plate is found to show the same trend, with zones of Adriatic provenance (Austro-Alpine unit and Southern Alps) found to be denser and those of European provenance (Helvetic zone and Tauern Window) to be less dense. This suggests that the respective plates and related terranes had similar crustal properties to the present-day ones prior to orogenesis. The model generated here is available for open-access use to further discussions about the crust in the region.
Y1  - 2019
U6  - https://doi.org/10.5194/se-10-2073-2019
SN  - 1869-9510
SN  - 1869-9529
VL  - 10
IS  - 6
SP  - 2073
EP  - 2088
PB  - Copernicus
CY  - Göttingen
ER  - 
TY  - JOUR
A1  - Cherubini, Yvonne
A1  - Cacace, Mauro
A1  - Scheck-Wenderoth, Magdalena
A1  - Moeck, Inga
A1  - Lewerenz, Björn
T1  - Controls on the deep thermal field - implications from 3-D numerical simulations for the geothermal research site Groß Schönebeck
JF  - Environmental earth sciences
N2  - The deep thermal field in sedimentary basins can be affected by convection, conduction or both resulting from the structural inventory, physical properties of geological layers and physical processes taking place therein. For geothermal energy extraction, the controlling factors of the deep thermal field need to be understood to delineate favorable drill sites and exploitation compartments. We use geologically based 3-D finite element simulations to figure out the geologic controls on the thermal field of the geothermal research site Gro Schonebeck located in the E part of the North German Basin. Its target reservoir consists of Permian Rotliegend clastics that compose the lower part of a succession of Late Carboniferous to Cenozoic sediments, subdivided into several aquifers and aquicludes. The sedimentary succession includes a layer of mobilized Upper Permian Zechstein salt which plays a special role for the thermal field due to its high thermal conductivity. Furthermore, the salt is impermeable and due to its rheology decouples the fault systems in the suprasalt units from subsalt layers. Conductive and coupled fluid and heat transport simulations are carried out to assess the relative impact of different heat transfer mechanisms on the temperature distribution. The measured temperatures in 7 wells are used for model validation and show a better fit with models considering fluid and heat transport than with a purely conductive model. Our results suggest that advective and convective heat transport are important heat transfer processes in the suprasalt sediments. In contrast, thermal conduction mainly controls the subsalt layers. With a third simulation, we investigate the influence of a major permeable and of three impermeable faults dissecting the subsalt target reservoir and compare the results to the coupled model where no faults are integrated. The permeable fault may have a local, strong impact on the thermal, pressure and velocity fields whereas the impermeable faults only cause deviations of the pressure field.
KW  - Thermal field
KW  - Coupled fluid and heat transport
KW  - Faults
KW  - Groß beta Schönebeck
Y1  - 2013
U6  - https://doi.org/10.1007/s12665-013-2519-4
SN  - 1866-6280
SN  - 1866-6299
VL  - 70
IS  - 8
SP  - 3619
EP  - 3642
PB  - Springer
CY  - New York
ER  - 
TY  - JOUR
A1  - Kaiser, Björn Onno
A1  - Cacace, Mauro
A1  - Scheck-Wenderoth, Magdalena
T1  - Quaternary channels within the Northeast German Basin and their relevance on double diffusive convective transport processes -  constraints from 3-D thermohaline numerical simulations
JF  - Geochemistry, geophysics, geosystems
N2  - The internal geological structure of the Northeast German Basin (NEGB) is affected by intense salt diapirism and by the presence of several stratified aquifer complexes of regional relevance. The shallow Quaternary to late Tertiary freshwater aquifer is separated from the underlying Mesozoic saline aquifers by an embedded Tertiary clay enriched aquitard (Rupelian Aquitard). An important feature of this aquitard is that hydraulic connections between the upper and lower aquifers do exist in areas where the Rupelian Aquitard is missing (hydrogeological windows). Three-dimensional thermohaline numerical simulations are carried out to investigate the effects of such hydrogeological windows in the Rupelian Aquitard on the resulting groundwater, temperature, and salinity distributions. Numerical results suggest that hydrogeological windows act as preferential domains of hydraulic interconnectivity between the different aquifers at depth and enable vigorous heat and mass transport which causes a mixing of warm and saline groundwater with cold and less saline groundwater within both aquifers. In areas where the Rupelian Aquitard confines the Mesozoic aquifer, dissolved solutes from major salt structures are transported laterally giving rise to plumes of variable salinity content ranging from few hundreds of meters to several tens of kilometers. Furthermore, destabilizing thermal buoyancy forces may overwhelm counteracting stabilizing salinity induced forces offside of salt domes. This may result in buoyant upward groundwater flow transporting heat and mass to shallower levels within the same Mesozoic Aquifer.
KW  - double diffusive convection
KW  - thermohaline processes
KW  - numerical simulations
KW  - salt structures
KW  - Northeast German Basin
KW  - quarternary channels
Y1  - 2013
U6  - https://doi.org/10.1002/ggge.20192
SN  - 1525-2027
VL  - 14
IS  - 8
SP  - 3156
EP  - 3175
PB  - American Geophysical Union
CY  - Washington
ER  - 
TY  - JOUR
A1  - Noack, Vera
A1  - Scheck-Wenderoth, Magdalena
A1  - Cacace, Mauro
T1  - Sensitivity of 3D thermal models to the choice of boundary conditions and thermal properties: a case study for the area of Brandenburg (NE German Basin)
JF  - Environmental earth sciences
N2  - Based on newly available data of both, the structural setting and thermal properties, we compare 3D thermal models for the area of Brandenburg, located in the Northeast German Basin, to assess the sensitivity of our model results. The structural complexity of the basin fill is given by the configuration of the Zechstein salt with salt diapirs and salt pillows. This special configuration is very relevant for the thermal calculations because salt has a distinctly higher thermal conductivity than other sediments. We calculate the temperature using a FEMethod to solve the steady state heat conduction equation in 3D. Based on this approach, we evaluate the sensitivity of the steady-state conductive thermal field with respect to different lithospheric configurations and to the assigned thermal properties. We compare three different thermal models: (a) a crustal-scale model including a homogeneous crust, (b) a new lithosphere-scale model including a differentiated crust and (c) a crustal-scale model with a stepwise variation of measured thermal properties. The comparison with measured temperatures from different structural locations of the basin shows a good fit to the temperature predictions for the first two models, whereas the third model is distinctly colder. This indicates that effective thermal conductivities may be different from values determined by measurements on rock samples. The results suggest that conduction is the main heat transport mechanism in the Brandenburg area.
KW  - Conductive thermal field
KW  - 3D thermal model
KW  - Lithosphere-asthenosphere boundary
KW  - Zechstein salt
KW  - Brandenburg
KW  - Northeast German Basin
Y1  - 2012
U6  - https://doi.org/10.1007/s12665-012-1614-2
SN  - 1866-6280
VL  - 67
IS  - 6
SP  - 1695
EP  - 1711
PB  - Springer
CY  - New York
ER  - 
TY  - JOUR
A1  - Kaiser, Bjoern Onno
A1  - Cacace, Mauro
A1  - Scheck-Wenderoth, Magdalena
A1  - Lewerenz, Bjoern
T1  - Characterization of main heat transport processes in the Northeast German Basin constraints from 3-D numerical models
JF  - Geochemistry, geophysics, geosystems
N2  - To investigate and quantify main physical heat driving processes affecting the present-day subsurface thermal field, we study a complex geological setting, the Northeast German Basin (NEGB). The internal geological structure of the NEGB is characterized by the presence of a relatively thick layer of Permian Zechstein salt (up to 5000 m), which forms many salt diapirs and pillows locally reaching nearly the surface. By means of three-dimensional numerical simulations we explore the role of heat conduction, pressure, and density driven groundwater flow as well as fluid viscosity related effects. Our results suggest that the regional temperature distribution within the basin results from interactions between regional pressure forces as driven by topographic gradients and thermal diffusion locally enhanced by thermal conductivity contrasts between the different sedimentary rocks with the highly conductive salt playing a prominent role. In contrast, buoyancy forces triggered by temperature-dependent fluid density variations are demonstrated to affect only locally the internal thermal configuration. Locations, geometry, and wavelengths of convective thermal anomalies are mainly controlled by the permeability field and thickness values of the respective geological layers.
KW  - advection
KW  - convection
KW  - coupled fluid and heat transport
KW  - numerical simulations
KW  - Northeast German Basin
KW  - salt structures
Y1  - 2011
U6  - https://doi.org/10.1029/2011GC003535
SN  - 1525-2027
VL  - 12
IS  - 13
PB  - American Geophysical Union
CY  - Washington
ER  - 
TY  - JOUR
A1  - Ziegler, Moritz O.
A1  - Heidbach, Oliver
A1  - Reinecker, John
A1  - Przybycin, Anna M.
A1  - Scheck-Wenderoth, Magdalena
T1  - A multi-stage 3-D stress field modelling approach exemplified in the Bavarian Molasse Basin
JF  - Solid earth
Y1  - 2016
U6  - https://doi.org/10.5194/se-7-1365-2016
SN  - 1869-9510
SN  - 1869-9529
VL  - 7
SP  - 1365
EP  - 1382
PB  - Copernicus
CY  - Göttingen
ER  - 
TY  - JOUR
A1  - Spooner, Cameron
A1  - Scheck-Wenderoth, Magdalena
A1  - Cacace, Mauro
A1  - Anikiev, Denis
T1  - How Alpine seismicity relates to lithospheric strength
JF  - International journal of earth sciences
N2  - Despite the amount of research focussed on the Alpine orogen, different hypotheses still exist regarding varying spatial seismicity distribution patterns throughout the region. Previous measurement-constrained regional 3D models of lithospheric density distribution and thermal field facilitate the generation of a data-based rheological model of the region. 
In this study, we compute the long-term lithospheric strength and compare its spatial variation to observed seismicity patterns. We demonstrate how strength maxima within the crust (similar to 1 GPa) and upper mantle (> 2 GPa) occur at temperatures characteristic of the onset of crystal plasticity in those rocks (crust: 200-400 degrees C; mantle: similar to 600 degrees C), with almost all seismicity occurring in these regions. Correlation in the northern and southern forelands between crustal and lithospheric strengths and seismicity show different patterns of event distribution, reflecting their different tectonic settings. Seismicity in the plate boundary setting of the southern foreland corresponds to the integrated lithospheric strength, occurring mainly in the weaker domains surrounding the strong Adriatic plate. In the intraplate setting of the northern foreland, seismicity correlates to modelled crustal strength, and it mainly occurs in the weaker and warmer crust beneath the Upper Rhine Graben. 
We, therefore, suggest that seismicity in the upper crust is linked to weak crustal domains, which are more prone to localise deformation promoting failure and, depending on the local properties of the fault, earthquakes at relatively lower levels of accumulated stress than their neighbouring stronger counterparts. Upper mantle seismicity at depths greater than modelled brittle conditions, can be either explained by embrittlement of the mantle due to grain-size sensitive deformation within domains of active or recent slab cooling, or by dissipative weakening mechanisms, such as thermal runaway from shear heating and/or dehydration reactions within an overly ductile mantle. 
Results generated in this study are available for open access use to further discussions on the region.
KW  - lithosphere
KW  - strength
KW  - rheology
KW  - 3D-Model
KW  - Alps
KW  - seismicity
Y1  - 2022
U6  - https://doi.org/10.1007/s00531-022-02174-5
SN  - 1437-3254
SN  - 1437-3262
VL  - 111
IS  - 4
SP  - 1201
EP  - 1221
PB  - Springer
CY  - Berlin ; Heidelberg
ER  - 
TY  - JOUR
A1  - Rodriguez Piceda, Constanza
A1  - Scheck-Wenderoth, Magdalena
A1  - Cacace, Mauro
A1  - Bott, Judith
A1  - Strecker, Manfred
T1  - Long-Term Lithospheric Strength and Upper-Plate Seismicity in the Southern Central Andes, 29 degrees-39 degrees S
JF  - Geochemistry, geophysics, geosystems
N2  - We examined the relationship between the mechanical strength of the lithosphere and the distribution of seismicity within the overriding continental plate of the southern Central Andes (SCA, 29 degrees-39 degrees S), where the oceanic Nazca Plate changes its subduction angle between 33 degrees S and 35 degrees S, from subhorizontal in the north (<5 degrees) to steep in the south (similar to 30 degrees). We computed the long-term lithospheric strength based on an existing 3D model describing variations in thickness, density, and temperature of the main geological units forming the lithosphere of the SCA and adjacent forearc and foreland regions. The comparison between our results and seismicity within the overriding plate (upper-plate seismicity) shows that most of the events occur within the modeled brittle domain of the lithosphere. The depth where the deformation mode switches from brittle frictional to thermally activated ductile creep provides a conservative lower bound to the seismogenic zone in the overriding plate of the study area. We also found that the majority of upper-plate earthquakes occurs within the realm of first-order contrasts in integrated strength (12.7-13.3 log Pam in the Andean orogen vs. 13.5-13.9 log Pam in the forearc and the foreland). Specific conditions characterize the mechanically strong northern foreland of the Andes, where seismicity is likely explained by the effects of slab steepening.
KW  - subduction zone
KW  - Andes
KW  - rheology
KW  - seismicity
KW  - flat-slab
Y1  - 2022
U6  - https://doi.org/10.1029/2021GC010171
SN  - 1525-2027
VL  - 23
IS  - 3
PB  - American Geophysical Union
CY  - Washington
ER  - 
TY  - JOUR
A1  - Freymark, Jessica
A1  - Bott, Judith
A1  - Cacace, Mauro
A1  - Ziegler, Moritz 0.
A1  - Scheck-Wenderoth, Magdalena
T1  - Influence of the Main Border Faults on the 3D Hydraulic Field of the Central Upper Rhine Graben
JF  - Geofluids
N2  - The Upper Rhine Graben (URG) is an active rift with a high geothermal potential. Despite being a well-studied area, the three-dimensional interaction of the main controlling factors of the thermal and hydraulic regime is still not fully understood. Therefore, we have used a data-based 3D structural model of the lithological configuration of the central URG for some conceptual numerical experiments of 3D coupled simulations of fluid and heat transport. To assess the influence of the main faults bordering the graben on the hydraulic and the deep thermal field, we carried out a sensitivity analysis on fault width and permeability. Depending on the assigned width and permeability of the main border faults, fluid velocity and temperatures are affected only in the direct proximity of the respective border faults. Hence, the hydraulic characteristics of these major faults do not significantly influence the graben-wide groundwater flow patterns. Instead, the different scenarios tested provide a consistent image of the main characteristics of fluid and heat transport as they have in common: (1) a topography-driven basin-wide fluid flow perpendicular to the rift axis from the graben shoulders to the rift center, (2) a N/NE-directed flow parallel to the rift axis in the center of the rift and, (3) a pronounced upflow of hot fluids along the rift central axis, where the streams from both sides of the rift merge. This upflow axis is predicted to occur predominantly in the center of the URG (northern and southern model area) and shifted towards the eastern boundary fault (central model area).
Y1  - 2019
U6  - https://doi.org/10.1155/2019/7520714
SN  - 1468-8115
SN  - 1468-8123
PB  - Wiley-Hindawi
CY  - London
ER  -