Active Oceanic Detachment Faulting at the Ultraslow Spreading Mohns-Knipovich Ridge Bend: A 12 Month Microseismicity Study

At ultraslow spreading ridges magma supply is limited and spreading is often accommodated by tectonic extension, resulting in large offset normal faults. When these initially steep normal faults roll over to lower angles at shallow depths they are called detachment faults. They can expose mantle roc...

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Bibliographic Details
Main Author: Pilot, Matthias
Format: Thesis
Language:unknown
Published: 2022
Subjects:
Arctic
Knipovich Ridge
Online Access:https://epic.awi.de/id/eprint/56289/
https://hdl.handle.net/10013/epic.633c6178-2fcd-4bee-bb5d-81b124f76ac2
id ftawi:oai:epic.awi.de:56289
record_format openpolar
spelling ftawi:oai:epic.awi.de:56289 2023-05-15T15:15:07+02:00 Active Oceanic Detachment Faulting at the Ultraslow Spreading Mohns-Knipovich Ridge Bend: A 12 Month Microseismicity Study Pilot, Matthias 2022-05-22 https://epic.awi.de/id/eprint/56289/ https://hdl.handle.net/10013/epic.633c6178-2fcd-4bee-bb5d-81b124f76ac2 unknown Pilot, M. (2022) Active Oceanic Detachment Faulting at the Ultraslow Spreading Mohns-Knipovich Ridge Bend: A 12 Month Microseismicity Study , Master thesis, University of Bremen. hdl:10013/epic.633c6178-2fcd-4bee-bb5d-81b124f76ac2 EPIC388 p. Thesis notRev 2022 ftawi 2022-06-26T23:12:18Z At ultraslow spreading ridges magma supply is limited and spreading is often accommodated by tectonic extension, resulting in large offset normal faults. When these initially steep normal faults roll over to lower angles at shallow depths they are called detachment faults. They can expose mantle rocks at the seafloor and act as pathways for hydrothermal fluid circulation. With only a few long-term seismicity studies of active oceanic detachment faults, many of the ongoing deformation processes are still under debate. While earthquakes appear to delineate the detachment surface, seismicity within the footwall of the detachment has been contrarily related to either compressional stresses from bending-related forces or extensional stress due to solid-block rotation. This thesis aims to provide further insights into the seismic characteristics of an active spreading system and the processes related to active oceanic detachment faulting. A microseismicity dataset was recorded during a 12 months Ocean Bottom Seismometer deployment at the Mohns-Knipovich Ridge bend along the ultraslow spreading Arctic Mid Ocean Ridge system. From the whole dataset microearthquakes were extracted and subsequently picked with automatic earthquake detection and phase picking algorithms. For this thesis a sub-catalogue of the strongest 1534 events was extracted. It consisted of events with phase picks on at least seven stations which were manually re-picked. To find the best location procedure, two velocity models and two location algorithms with station corrections derived for each of the procedures were used. From the results of the best location procedure 1215 well-constrained events were selected for further interpretation. The location results reveal a shallowing brittle-ductile transition zone from ∼6-5 km depths towards the Loki’s Castle hydrothermal vent field. This could indicate the presence of a heat source beneath the axial volcanic ridge. An active detachment fault, dipping at ∼70 ◦ towards the SE, shows continuous seismic ... Thesis Arctic Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center) Arctic Knipovich Ridge ENVELOPE(7.074,7.074,75.712,75.712)
institution Open Polar
collection Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center)
op_collection_id ftawi
language unknown
description At ultraslow spreading ridges magma supply is limited and spreading is often accommodated by tectonic extension, resulting in large offset normal faults. When these initially steep normal faults roll over to lower angles at shallow depths they are called detachment faults. They can expose mantle rocks at the seafloor and act as pathways for hydrothermal fluid circulation. With only a few long-term seismicity studies of active oceanic detachment faults, many of the ongoing deformation processes are still under debate. While earthquakes appear to delineate the detachment surface, seismicity within the footwall of the detachment has been contrarily related to either compressional stresses from bending-related forces or extensional stress due to solid-block rotation. This thesis aims to provide further insights into the seismic characteristics of an active spreading system and the processes related to active oceanic detachment faulting. A microseismicity dataset was recorded during a 12 months Ocean Bottom Seismometer deployment at the Mohns-Knipovich Ridge bend along the ultraslow spreading Arctic Mid Ocean Ridge system. From the whole dataset microearthquakes were extracted and subsequently picked with automatic earthquake detection and phase picking algorithms. For this thesis a sub-catalogue of the strongest 1534 events was extracted. It consisted of events with phase picks on at least seven stations which were manually re-picked. To find the best location procedure, two velocity models and two location algorithms with station corrections derived for each of the procedures were used. From the results of the best location procedure 1215 well-constrained events were selected for further interpretation. The location results reveal a shallowing brittle-ductile transition zone from ∼6-5 km depths towards the Loki’s Castle hydrothermal vent field. This could indicate the presence of a heat source beneath the axial volcanic ridge. An active detachment fault, dipping at ∼70 ◦ towards the SE, shows continuous seismic ...
format Thesis
author Pilot, Matthias
spellingShingle Pilot, Matthias
Active Oceanic Detachment Faulting at the Ultraslow Spreading Mohns-Knipovich Ridge Bend: A 12 Month Microseismicity Study
author_facet Pilot, Matthias
author_sort Pilot, Matthias
title Active Oceanic Detachment Faulting at the Ultraslow Spreading Mohns-Knipovich Ridge Bend: A 12 Month Microseismicity Study
title_short Active Oceanic Detachment Faulting at the Ultraslow Spreading Mohns-Knipovich Ridge Bend: A 12 Month Microseismicity Study
title_full Active Oceanic Detachment Faulting at the Ultraslow Spreading Mohns-Knipovich Ridge Bend: A 12 Month Microseismicity Study
title_fullStr Active Oceanic Detachment Faulting at the Ultraslow Spreading Mohns-Knipovich Ridge Bend: A 12 Month Microseismicity Study
title_full_unstemmed Active Oceanic Detachment Faulting at the Ultraslow Spreading Mohns-Knipovich Ridge Bend: A 12 Month Microseismicity Study
title_sort active oceanic detachment faulting at the ultraslow spreading mohns-knipovich ridge bend: a 12 month microseismicity study
publishDate 2022
url https://epic.awi.de/id/eprint/56289/
https://hdl.handle.net/10013/epic.633c6178-2fcd-4bee-bb5d-81b124f76ac2
long_lat ENVELOPE(7.074,7.074,75.712,75.712)
geographic Arctic
Knipovich Ridge
geographic_facet Arctic
Knipovich Ridge
genre Arctic
genre_facet Arctic
op_source EPIC388 p.
op_relation Pilot, M. (2022) Active Oceanic Detachment Faulting at the Ultraslow Spreading Mohns-Knipovich Ridge Bend: A 12 Month Microseismicity Study , Master thesis, University of Bremen. hdl:10013/epic.633c6178-2fcd-4bee-bb5d-81b124f76ac2
_version_ 1766345490210750464

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