Structural style and neotectonic activity along the Harz Boundary Fault, northern German: a multimethod approach integrating geophysics, outcrop data and numerical simulations

We present new evidence for neotectonic activity along the Harz Boundary Fault, a Cretaceous reverse fault that represents a key structure in northern Germany. For the fault analysis, we use a multimethod approach, integrating outcrop data, luminescene dating, shear wave seismics, electrical resisti...

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Main Authors: Müller, Katharina, Polom, Ulrich, Winsemann, Jutta, Steffen, Holger, Tsukamoto, Sumiko, Günther, Thomas, Igel, Jan, Spies, Thomas, Lege, Thomas, Frechen, Manfred, Franzke, Hans‑Joachim, Brandes, Christian
Format: Article in Journal/Newspaper
Language:unknown
Published: Berlin 2020
Subjects:
Electrical resistivity tomography ERT
Glacial isostatic adjustment GIA
Harz Boundary Fault
Lateglacial
Luminescence dating
Neotectonics
Northern Germany
Numerical simulations
Shear wave seismics
550
Fennoscandian
Ice Sheet
Online Access:https://dx.doi.org/10.34657/6285
https://oa.tib.eu/renate/handle/123456789/7238
id ftdatacite:10.34657/6285
record_format openpolar
spelling ftdatacite:10.34657/6285 2023-05-15T16:13:10+02:00 Structural style and neotectonic activity along the Harz Boundary Fault, northern German: a multimethod approach integrating geophysics, outcrop data and numerical simulations Müller, Katharina Polom, Ulrich Winsemann, Jutta Steffen, Holger Tsukamoto, Sumiko Günther, Thomas Igel, Jan Spies, Thomas Lege, Thomas Frechen, Manfred Franzke, Hans‑Joachim Brandes, Christian 2020 https://dx.doi.org/10.34657/6285 https://oa.tib.eu/renate/handle/123456789/7238 unknown Berlin Heidelberg : Springer Creative Commons Attribution 4.0 International CC BY 4.0 Unported https://creativecommons.org/licenses/by/4.0/legalcode cc-by-4.0 CC-BY Electrical resistivity tomography ERT Glacial isostatic adjustment GIA Harz Boundary Fault Lateglacial Luminescence dating Neotectonics Northern Germany Numerical simulations Shear wave seismics 550 CreativeWork article 2020 ftdatacite https://doi.org/10.34657/6285 2022-03-10T12:44:35Z We present new evidence for neotectonic activity along the Harz Boundary Fault, a Cretaceous reverse fault that represents a key structure in northern Germany. For the fault analysis, we use a multimethod approach, integrating outcrop data, luminescene dating, shear wave seismics, electrical resistivity tomography (ERT) and numerical simulations. A recent sinkhole at the SSW-ward dipping and WNW–ESE striking Harz Boundary Fault exposes a NNE-ward dipping and WNW–ESE striking planar fault surface that cuts through unconsolidated debris-flow deposits thus pointing to young Lateglacial tectonic activity. The fault shows a polyphase evolution with initial normal fault movement and a later reactivation as an oblique fault with reverse and strike-slip components. A shear wave seismic profile was acquired to analyse the geometry of the fault and show that the Harz Boundary Fault is steeply dipping and likely has branches. Partly, these branches propagate into overlying alluvial-fan deposits that are probably Pleniglacial to Lateglacial in age. The outcrop data in combination with the seismic data give evidence for a splay fault system with steep back-thrusts. One of these back-thrusts is most likely the NNE-ward dipping fault that is exposed in the sinkhole. The lateral extent of the fault was mapped with electrical resistivity tomography (ERT) profiles. The timing of fault movement was estimated based on optically stimulated luminescence dating of the faulted debris-flow deposits using both quartz and feldspar minerals. Consistent feldspar and quartz ages indicate a good bleaching of the sediment prior to deposition. The results imply fault movements post-dating ~ 15 ka. Numerical simulations of glacio isostatic adjustment (GIA)-related changes in the Coulomb failure stress regime at the Harz Boundary Fault underpin the assumption that the fault was reactivated during the Lateglacial due to stress changes induced by the decay of the Late Pleistocene (Weichselian) Fennoscandian ice sheet. © 2020, The Author(s). Article in Journal/Newspaper Fennoscandian Ice Sheet DataCite Metadata Store (German National Library of Science and Technology)
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
topic Electrical resistivity tomography ERT
Glacial isostatic adjustment GIA
Harz Boundary Fault
Lateglacial
Luminescence dating
Neotectonics
Northern Germany
Numerical simulations
Shear wave seismics
550
spellingShingle Electrical resistivity tomography ERT
Glacial isostatic adjustment GIA
Harz Boundary Fault
Lateglacial
Luminescence dating
Neotectonics
Northern Germany
Numerical simulations
Shear wave seismics
550
Müller, Katharina
Polom, Ulrich
Winsemann, Jutta
Steffen, Holger
Tsukamoto, Sumiko
Günther, Thomas
Igel, Jan
Spies, Thomas
Lege, Thomas
Frechen, Manfred
Franzke, Hans‑Joachim
Brandes, Christian
Structural style and neotectonic activity along the Harz Boundary Fault, northern German: a multimethod approach integrating geophysics, outcrop data and numerical simulations
topic_facet Electrical resistivity tomography ERT
Glacial isostatic adjustment GIA
Harz Boundary Fault
Lateglacial
Luminescence dating
Neotectonics
Northern Germany
Numerical simulations
Shear wave seismics
550
description We present new evidence for neotectonic activity along the Harz Boundary Fault, a Cretaceous reverse fault that represents a key structure in northern Germany. For the fault analysis, we use a multimethod approach, integrating outcrop data, luminescene dating, shear wave seismics, electrical resistivity tomography (ERT) and numerical simulations. A recent sinkhole at the SSW-ward dipping and WNW–ESE striking Harz Boundary Fault exposes a NNE-ward dipping and WNW–ESE striking planar fault surface that cuts through unconsolidated debris-flow deposits thus pointing to young Lateglacial tectonic activity. The fault shows a polyphase evolution with initial normal fault movement and a later reactivation as an oblique fault with reverse and strike-slip components. A shear wave seismic profile was acquired to analyse the geometry of the fault and show that the Harz Boundary Fault is steeply dipping and likely has branches. Partly, these branches propagate into overlying alluvial-fan deposits that are probably Pleniglacial to Lateglacial in age. The outcrop data in combination with the seismic data give evidence for a splay fault system with steep back-thrusts. One of these back-thrusts is most likely the NNE-ward dipping fault that is exposed in the sinkhole. The lateral extent of the fault was mapped with electrical resistivity tomography (ERT) profiles. The timing of fault movement was estimated based on optically stimulated luminescence dating of the faulted debris-flow deposits using both quartz and feldspar minerals. Consistent feldspar and quartz ages indicate a good bleaching of the sediment prior to deposition. The results imply fault movements post-dating ~ 15 ka. Numerical simulations of glacio isostatic adjustment (GIA)-related changes in the Coulomb failure stress regime at the Harz Boundary Fault underpin the assumption that the fault was reactivated during the Lateglacial due to stress changes induced by the decay of the Late Pleistocene (Weichselian) Fennoscandian ice sheet. © 2020, The Author(s).
format Article in Journal/Newspaper
author Müller, Katharina
Polom, Ulrich
Winsemann, Jutta
Steffen, Holger
Tsukamoto, Sumiko
Günther, Thomas
Igel, Jan
Spies, Thomas
Lege, Thomas
Frechen, Manfred
Franzke, Hans‑Joachim
Brandes, Christian
author_facet Müller, Katharina
Polom, Ulrich
Winsemann, Jutta
Steffen, Holger
Tsukamoto, Sumiko
Günther, Thomas
Igel, Jan
Spies, Thomas
Lege, Thomas
Frechen, Manfred
Franzke, Hans‑Joachim
Brandes, Christian
author_sort Müller, Katharina
title Structural style and neotectonic activity along the Harz Boundary Fault, northern German: a multimethod approach integrating geophysics, outcrop data and numerical simulations
title_short Structural style and neotectonic activity along the Harz Boundary Fault, northern German: a multimethod approach integrating geophysics, outcrop data and numerical simulations
title_full Structural style and neotectonic activity along the Harz Boundary Fault, northern German: a multimethod approach integrating geophysics, outcrop data and numerical simulations
title_fullStr Structural style and neotectonic activity along the Harz Boundary Fault, northern German: a multimethod approach integrating geophysics, outcrop data and numerical simulations
title_full_unstemmed Structural style and neotectonic activity along the Harz Boundary Fault, northern German: a multimethod approach integrating geophysics, outcrop data and numerical simulations
title_sort structural style and neotectonic activity along the harz boundary fault, northern german: a multimethod approach integrating geophysics, outcrop data and numerical simulations
publisher Berlin
publishDate 2020
url https://dx.doi.org/10.34657/6285
https://oa.tib.eu/renate/handle/123456789/7238
genre Fennoscandian
Ice Sheet
genre_facet Fennoscandian
Ice Sheet
op_rights Creative Commons Attribution 4.0 International
CC BY 4.0 Unported
https://creativecommons.org/licenses/by/4.0/legalcode
cc-by-4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.34657/6285
_version_ 1765998781458808832

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