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  • 1
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    Lithospheric Control on Asthenospheric Flow From the Iceland Plume: 3-D Density Modeling of the Jan Mayen-East Greenland Region, NE Atlantic (2018)
    American Geophysical Union
    Details
    Publication Date: 2018-10-01
    Description: The density structure of the oceanic lithosphere north of Iceland is key for understanding the effects of the Iceland plume on the greater Jan Mayen-East Greenland Region. We obtain the 3-D density structure of the sediments and the crust from regional reflection and refraction seismic lines. The temperature and related density structures of the mantle between 50 and 250 km are derived from a shear wave velocity (Vs) tomography model. To assess the density between the Moho and 50-km depth, we combine forward and inverse 3-D gravity modeling. Beneath the Middle Kolbeinsey Ridge (MKR) region, a deep, broad negative mantle density anomaly occurs under the Kolbeinsey Ridge. It is overlain by a narrower uppermost mantle NE-SW elongated negative density anomaly, which is increasingly displaced eastward of the spreading axis northward. It crosses the West Jan Mayen Fracture Zone and becomes weaker approaching the Mohn's spreading ridge. The effect of this anomaly is consistent with significantly shallower basement on the eastern side of the MKR. We interpret this as the result of thermal erosion of the lithosphere by hot asthenospheric flow out from the Iceland plume, possibly the main driver for several eastward jumps of the MKR during the last 5.5 Ma. The cause for the deviation of the flow may be that the West Jan Mayen Fracture Zone is easier to cross in a region where the difference in lithospheric thickness is small. That implies that the bottom lithospheric topography exerts a regional but not local influence on upper asthenospheric flow. ©2018. American Geophysical Union. All Rights Reserved.
    Print ISSN: 2169-9313
    Electronic ISSN: 2169-9356
    Topics: Geosciences , Physics
    Published by American Geophysical Union
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  • 2
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    The Kenya rift revisited: insights into lithospheric strength through data-driven 3-D gravity and thermal modelling (2017)
    Copernicus
    Details
    Publication Date: 2017-01-16
    Description: We present three-dimensional (3-D) models that describe the present-day thermal and rheological state of the lithosphere of the greater Kenya rift region aiming at a better understanding of the rift evolution, with a particular focus on plume–lithosphere interactions. The key methodology applied is the 3-D integration of diverse geological and geophysical observations using gravity modelling. Accordingly, the resulting lithospheric-scale 3-D density model is consistent with (i) reviewed descriptions of lithological variations in the sedimentary and volcanic cover, (ii) known trends in crust and mantle seismic velocities as revealed by seismic and seismological data and (iii) the observed gravity field. This data-based model is the first to image a 3-D density configuration of the crystalline crust for the entire region of Kenya and northern Tanzania. An upper and a basal crustal layer are differentiated, each composed of several domains of different average densities. We interpret these domains to trace back to the Precambrian terrane amalgamation associated with the East African Orogeny and to magmatic processes during Mesozoic and Cenozoic rifting phases. In combination with seismic velocities, the densities of these crustal domains indicate compositional differences. The derived lithological trends have been used to parameterise steady-state thermal and rheological models. These models indicate that crustal and mantle temperatures decrease from the Kenya rift in the west to eastern Kenya, while the integrated strength of the lithosphere increases. Thereby, the detailed strength configuration appears strongly controlled by the complex inherited crustal structure, which may have been decisive for the onset, localisation and propagation of rifting.
    Print ISSN: 1869-9510
    Electronic ISSN: 1869-9529
    Topics: Geosciences
    Published by Copernicus on behalf of European Geosciences Union.
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  • 3
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    3‐D Modeling of Vertical Gravity Gradients and the Delimitation of Tectonic Boundaries: The Caribbean Oceanic Domain as a Case Study (2019)
    American Geophysical Union
    Details
    Publication Date: 2019-11-01
    Electronic ISSN: 1525-2027
    Topics: Chemistry and Pharmacology , Geosciences , Physics
    Published by American Geophysical Union
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  • 4
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    VelocityConversion (2017)
    GFZ Data Services
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    Publication Date: 2022-02-17
    Description: Abstract
    Description: This code is a python implementation of the p- and s-wave velocity to density conversion approach after Goes et al. (2000). The implementation has been optimised for regular 3D grids using lookup tables instead of Newton iterations.Goes et al. (2000) regard the expansion coefficient as temperature dependent using the relation by Saxena and Shen (1992). In `Conversion.py`, the user can additionally choose between a constant expansion coefficient or a pressure- and temperature dependent coefficient that was derived from Hacker and Abers (2004).For detailed information on the physics behind the approach have a look at the original paper by Goes et al. (2000). Up-to-date contact information are given on the author's github profile https://github.com/cmeessen.
    Keywords: seismology ; geophysics ; geoscience ; conversion ; upper mantle ; temperature ; density ; seismic velocity
    Type: Software
    Format: 2135347 Bytes
    Format: 4 Files
    Format: application/x-zip-compressed
    Format: application/octet-stream
    Format: application/octet-stream
    Format: application/octet-stream
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  • 5
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    IGMAS+: Interactive Gravity and Magnetic Application System (2020)
    GFZ Data Services
    Details
    Publication Date: 2023-12-09
    Description: Abstract
    Description: IGMAS+ is a software for 3-D modelling of potential fields and its derivatives under the condition of constraining data and independent information. It comes with tools for forward and inverse modelling. IGMAS+ has a long history starting 1988 and has seen continuous improvement since then with input by many contributors. Since 2019, IGMAS+ is maintained and developed at The Helmholtz Centre Potsdam - GFZ German Research Centre for Geosciences by the staff of Section 4.5 – Basin Modelling and ID2 – eScience Centre with strong ongoing support by H.-J. Götze and S. Schmidt from CAU Kiel. The official webpage of IGMAS+ is available at https://www.gfz-potsdam.de/igmas/. Each major version of IGMAS+ will be assigned with a new DOI. Intermediate releases including changelog can be found at https://git.gfz-potsdam.de/igmas/igmas-releases/-/releases/.
    Description: Methods
    Description: In IGMAS+ the analytical solution of the volume integral for the gravity and magnetic effect of a homogeneous body is based on the reduction of the three-folded integral to an integral over the bounding polyhedrons (in IGMAS polyhedrons are built by triangles). The original algorithm has been extended to cover all elements of the gravity and magnetic tensors as well. Optimized storage enables extreme fast inversion of material parameters and changes to the model geometry and this flexibility makes geometry changes easy. Immediately after each change, model geometry is updated and the field components are recalculated. Because of the triangular model structure, IGMAS+ can handle complex structures (multi Z surfaces) like the overhangs of salt domes very well. It handles remanent and induced magnetisation of geological bodies and was applied to the interpretation of borehole gravity and magnetics. Modelling is constrained by structural input from independent data sources, such as seismic data, and is essential toward true integration of 3D thermal modelling or even Full Waveform Inversion. Geophysical investigations may cover huge areas of several thousand square kilometres but also models of Applied Geophysics at a meter scale. Due to the curvature of the Earth, the use of spherical geometries and calculations is necessary. IGMAS+ can be used for both flat (regional) and spherical models (global) in 3D.
    Description: TechnicalInfo
    Description: List of changes for Release 1.3.8656 Fixed •Custom projection using GeoTools (#22) •Voxel density units (#74) •Dark/light theme selector not working for the first start (#83) •The size of windows for text input (#76) •Consistent user experience for all ptaforms (#69) •Build problem (#65) •Bug with reading "calculated (measured) Geoid" from ".station" format (#38) •Build problem (#59) •Spherical calculation settings of "Max. Length" (#37) •An error occured when section was defined with normal (0, -1) (#35) •Bug when save project button is disabled while reaching recent items directory (#4) •EPSG codes not appearing in projection lists (#28) •Multiple cutter showed anomaly field in white (#36) •Residual field is in mGal/km when the gradients are calculated in Eötvös (#36) •Wrong factor for magnetic field calculation with mT (#29) •Bug related to memory settings (#31) •Image export •WorldWind renderer •Linux executables Added •GFZ branding in installer (#14) •Calculation of body volume (#32) •GeoTools gt-referencing projection (#78) •New flatlaf design themes •Integrate update check (#43) •Notification about missing coordinate system when starting spherical approximation (#16) •2-D View icon to the toolbar •Warning for the missing projection •This changelog Changed •Migrated to latest JOGL bindings (#84) •Name of the app after installation changed to IGMAS+ (#81) •About window (#53) •Switch from JSyntaxPane to RSyntaxTextArea (#71) •Migrated to new truelicense version v4 (#56) •Using "imported" instead of "measured" for Geoid for export/import (#41) •Disabled SSL certificate validation for WorldWind tile server •Viewboard logo - GFZ logo is used now (#14) •Switched to latest jython 2.7.2b2 •Switched to java8 as minimum requirement •Switched to the latest parsii library •Swtiched to the latest proj4j library •Updated main logo •Updated installer •Version numbers will now be generated following [major].[minor].[ci_pipeline_id]-[commit_hash]-[testing]. Removed •toolbox3d dependency (#57) •Geometry inversion from installer (#33) •Unsupported cluster installer
    Keywords: gravity ; potential field ; magnetics ; modelling ; software ; EARTH SCIENCE ; EARTH SCIENCE 〉 SOLID EARTH ; EARTH SCIENCE 〉 SOLID EARTH 〉 GEOMAGNETISM 〉 MAGNETIC FIELD ; EARTH SCIENCE 〉 SOLID EARTH 〉 GRAVITY/GRAVITATIONAL FIELD ; science 〉 natural science 〉 earth science 〉 geophysics
    Type: Software , Software
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    DATA GFZ
  • 6
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    3‐D Modeling of Vertical Gravity Gradients and the Delimitation of Tectonic Boundaries: The Caribbean Oceanic Domain as a Case Study (2021)
    Details
    Publication Date: 2021-07-01
    Description: Geophysical data acquisition in oceanic domains is challenging, implying measurements with low and/or nonhomogeneous spatial resolution. The evolution of satellite gravimetry and altimetry techniques allows testing 3‐D density models of the lithosphere, taking advantage of the high spatial resolution and homogeneous coverage of satellites. However, it is not trivial to discretise the source of the gravity field at different depths. Here, we propose a new method for inferring tectonic boundaries at the crustal level. As a novelty, instead of modeling the gravity anomalies and assuming a flat Earth approximation, we model the vertical gravity gradients (VGG) in spherical coordinates, which are especially sensitive to density contrasts in the upper layers of the Earth. To validate the methodology, the complex oceanic domain of the Caribbean region is studied, which includes different crustal domains with a tectonic history since Late Jurassic time. After defining a lithospheric starting model constrained by up‐to‐date geophysical data sets, we tested several a‐priory density distributions and selected the model with the minimum misfits with respect to the VGG calculated from the EIGEN‐6C4 data set. Additionally, the density of the crystalline crust was inferred by inverting the VGG field. Our methodology enabled us not only to refine, confirm, and/or propose tectonic boundaries in the study area but also to identify a new anomalous buoyant body, located in the South Lesser Antilles subduction zone, and high‐density bodies along the Greater, Lesser, and Leeward Antilles forearcs.
    Description: Plain Language Summary: The knowledge of the density structure of the different layers that compose the solid Earth is important, for example: in the study of earthquakes, in plate tectonics reconstructions, or for the modeling of petroleum systems. These density variations affect (in small scale) the intensity of the gravity field on each point of the Earth's surface. The gravity field can be globally measured with satellites, reaching areas where the direct measurements are expensive and time consuming, such as in the ocean. In this work, we propose a new methodology with the purpose of recognizing tectonic and/or terrain limits, located in the outer most layer of the solid Earth, named crystalline crust. We calculate the gravity field of different density distributions, using four layers: seawater, sediments, crystalline crust, and mantle (a layer located below the crust), and compare the results with satellite global measurements. With our methodology it is possible to refine, confirm, and/or propose terrain limits, but additionally, we are able to estimate the average density configuration of the crystalline crust. This methodology is validated in the oceanic domain of the Caribbean, where a complex geologic history exists, due to its evolution since approximately 144 million years ago.
    Description: Key Points: Vertical gravity gradients are especially sensitive to density contrasts in the upper layers of the lithosphere. We propose a new method for identifying tectonic boundaries based on the gradient's residuals and tested it in the Caribbean oceanic region. Using 3‐D lithospheric models, we forward modeled these gradients to infer the average density structure of the crystalline crust.
    Description: DAAD http://dx.doi.org/10.13039/501100001655
    Description: Erasmus+ http://dx.doi.org/10.13039/501100010790
    Description: CEMarin
    Description: Fundación para la promoción de la investigación y la tecnología‐Banco de la República de Colombia
    Description: Colciencias http://dx.doi.org/10.13039/100007637
    Keywords: 526.7 ; Vertical Gravity Gradients ; Gravity modelling ; Crustal structure ; Caribbean ; Tectonic boundaries ; 3D lithospheric model
    Type: article
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    CITATION GEO-LEO
  • 7
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    Interdisciplinary 3D potential field modelling of complex lithospheric structures by IGMAS+ (2021)
    Details
    Publication Date: 2022-12-01
    Description: We introduce an approach for 3D joint interpretation of potential fields and its derivatives under the condition of constraining data and information. The interactive 3D gravity and magnetic application IGMAS (Interactive Gravity and Magnetic Application System) has been around for more than 30 years, initially developed on a mainframe and then transferred to the first DOS PCs, before it was adapted to Linux in the ’90s and finally implemented as a cross-platform Java application with GUI. Since 2019 IGMAS+ is maintained and developed in the Helmholtz Centre Potsdam – GFZ German Research Centre by the staff of Section 4.5 – Basin Modelling and ID2 – eScience Centre. The core of IGMAS+ applies an analytical solution of the volume integral for the gravity and magnetic effect of a homogeneous body. It is based on the reduction of the three-folded integral to an integral over the bounding polyhedrons that are formed by triangles. Later the algorithm has been extended to cover all elements of the gravity tensor as well and the optimized storage enables fast leastsquares inversion of densities and changes to the model geometry and this flexibility makes geometry changes easy. Because of the triangular model structure of model interfaces, IGMAS can handle complex structures (multi- Z surfaces) like the overhangs of salt domes and variable densities due to voxelization. To account for the curvature of the Earth, we use spherical geometries. Therefore IGMAS+ is capable to handle models from big-scale to regional and small-scale models (meters) used in Applied Geophysics.
    Description: poster
    Keywords: ddc:550 ; Potential field modelling ; Complex modelling ; Visualization ; Software development
    Language: English
    Type: doc-type:conferenceObject
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    CITATION GEO-LEO
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