Image1_Response of a large deep-seated gravitational slope deformation to meteorological, seismic, and deglaciation drivers as measured by InSAR.pdf

We analyze the sensitivity of a large (area extent ∼3 km 2 ), deep-seated gravitational slope deformation (Fels slide, Alaska Range) to three specific drivers: (i) liquid surface water input from ERA-5 reanalysis snow melt and rainfall; (ii) locally projected seismic activity of Alaskan earthquakes;...

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Main Authors: Bernhard Rabus, Jeanine Engelbrecht, John J. Clague, Davide Donati, Doug Stead, Mirko Francioni
Format: Still Image
Language:unknown
Published: 2022
Subjects:
Solid Earth Sciences
Climate Science
Atmospheric Sciences not elsewhere classified
Exploration Geochemistry
Inorganic Geochemistry
Isotope Geochemistry
Organic Geochemistry
Geochemistry not elsewhere classified
Igneous and Metamorphic Petrology
Ore Deposit Petrology
Palaeontology (incl. Palynology)
Structural Geology
Tectonics
Volcanology
Geology not elsewhere classified
Seismology and Seismic Exploration
Glaciology
Hydrogeology
Natural Hazards
Quaternary Environments
Earth Sciences not elsewhere classified
Evolutionary Impacts of Climate Change
deep-seated gravitational slope deformation
remote sensing
interferometric synthetic aperture radar
geophysical time series analysis
Alaska
alaska range
glacier
Online Access:https://doi.org/10.3389/feart.2022.918901.s001
https://figshare.com/articles/figure/Image1_Response_of_a_large_deep-seated_gravitational_slope_deformation_to_meteorological_seismic_and_deglaciation_drivers_as_measured_by_InSAR_pdf/21607389
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record_format openpolar
spelling ftfrontimediafig:oai:figshare.com:article/21607389 2024-09-15T17:35:39+00:00 Image1_Response of a large deep-seated gravitational slope deformation to meteorological, seismic, and deglaciation drivers as measured by InSAR.pdf Bernhard Rabus Jeanine Engelbrecht John J. Clague Davide Donati Doug Stead Mirko Francioni 2022-11-23T04:41:01Z https://doi.org/10.3389/feart.2022.918901.s001 https://figshare.com/articles/figure/Image1_Response_of_a_large_deep-seated_gravitational_slope_deformation_to_meteorological_seismic_and_deglaciation_drivers_as_measured_by_InSAR_pdf/21607389 unknown doi:10.3389/feart.2022.918901.s001 https://figshare.com/articles/figure/Image1_Response_of_a_large_deep-seated_gravitational_slope_deformation_to_meteorological_seismic_and_deglaciation_drivers_as_measured_by_InSAR_pdf/21607389 CC BY 4.0 Solid Earth Sciences Climate Science Atmospheric Sciences not elsewhere classified Exploration Geochemistry Inorganic Geochemistry Isotope Geochemistry Organic Geochemistry Geochemistry not elsewhere classified Igneous and Metamorphic Petrology Ore Deposit Petrology Palaeontology (incl. Palynology) Structural Geology Tectonics Volcanology Geology not elsewhere classified Seismology and Seismic Exploration Glaciology Hydrogeology Natural Hazards Quaternary Environments Earth Sciences not elsewhere classified Evolutionary Impacts of Climate Change deep-seated gravitational slope deformation remote sensing interferometric synthetic aperture radar geophysical time series analysis Alaska Image Figure 2022 ftfrontimediafig https://doi.org/10.3389/feart.2022.918901.s001 2024-08-19T06:19:51Z We analyze the sensitivity of a large (area extent ∼3 km 2 ), deep-seated gravitational slope deformation (Fels slide, Alaska Range) to three specific drivers: (i) liquid surface water input from ERA-5 reanalysis snow melt and rainfall; (ii) locally projected seismic activity of Alaskan earthquakes; and (iii) lowering of Fels Glacier at the slide toe estimated from topographic data. A surface displacement map-series is derived from 1991 to 2016 spaceborne multi-sensor InSAR data (ERS, RADARSAT-1/2, ALOS, TerraSAR-X) using adaptive demodulation to unwrap interferograms of variable spatial resolution and quality. On this series we use independent component analysis (ICA) to uncover five displacement patterns that map to independently moving domains of the slide and then correlate the corresponding temporal pattern intensities with the suspected drivers. We find significant sub-annual correlation between displacement pattern intensities and seasonal water input variations. The correlation can be optimized, for each ICA pattern, by choosing appropriate values of temporal smoothing and lag to create depth-propagated versions of the water input driver. Lag time results ranging from one to 3 weeks relate to shallower and deeper propagations of water input, driving the different deformation patterns. For two of the deformation patterns, seasonal sensitivity to water input was strongly amplified by the 2002 M w 7.9 Denali earthquake. Sensitivity of these patterns remained high for 4 years until abruptly dropping to below pre-earthquake values, which suggests a highly non-linear modulation by the seismic driver. Other deformation patterns show a steady intensity increase that appears linked to the deglaciation driver. Despite these observations, the inter-annual variations in ICA pattern intensities show no clear predictability by individual drivers or driver combinations. This suggests that the mechanical and hydraulic evolution of the slide, especially after damaging events such as earthquakes or heavy rainfall, is a ... Still Image alaska range glacier Alaska Frontiers: Figshare
institution Open Polar
collection Frontiers: Figshare
op_collection_id ftfrontimediafig
language unknown
topic Solid Earth Sciences
Climate Science
Atmospheric Sciences not elsewhere classified
Exploration Geochemistry
Inorganic Geochemistry
Isotope Geochemistry
Organic Geochemistry
Geochemistry not elsewhere classified
Igneous and Metamorphic Petrology
Ore Deposit Petrology
Palaeontology (incl. Palynology)
Structural Geology
Tectonics
Volcanology
Geology not elsewhere classified
Seismology and Seismic Exploration
Glaciology
Hydrogeology
Natural Hazards
Quaternary Environments
Earth Sciences not elsewhere classified
Evolutionary Impacts of Climate Change
deep-seated gravitational slope deformation
remote sensing
interferometric synthetic aperture radar
geophysical time series analysis
Alaska
spellingShingle Solid Earth Sciences
Climate Science
Atmospheric Sciences not elsewhere classified
Exploration Geochemistry
Inorganic Geochemistry
Isotope Geochemistry
Organic Geochemistry
Geochemistry not elsewhere classified
Igneous and Metamorphic Petrology
Ore Deposit Petrology
Palaeontology (incl. Palynology)
Structural Geology
Tectonics
Volcanology
Geology not elsewhere classified
Seismology and Seismic Exploration
Glaciology
Hydrogeology
Natural Hazards
Quaternary Environments
Earth Sciences not elsewhere classified
Evolutionary Impacts of Climate Change
deep-seated gravitational slope deformation
remote sensing
interferometric synthetic aperture radar
geophysical time series analysis
Alaska
Bernhard Rabus
Jeanine Engelbrecht
John J. Clague
Davide Donati
Doug Stead
Mirko Francioni
Image1_Response of a large deep-seated gravitational slope deformation to meteorological, seismic, and deglaciation drivers as measured by InSAR.pdf
topic_facet Solid Earth Sciences
Climate Science
Atmospheric Sciences not elsewhere classified
Exploration Geochemistry
Inorganic Geochemistry
Isotope Geochemistry
Organic Geochemistry
Geochemistry not elsewhere classified
Igneous and Metamorphic Petrology
Ore Deposit Petrology
Palaeontology (incl. Palynology)
Structural Geology
Tectonics
Volcanology
Geology not elsewhere classified
Seismology and Seismic Exploration
Glaciology
Hydrogeology
Natural Hazards
Quaternary Environments
Earth Sciences not elsewhere classified
Evolutionary Impacts of Climate Change
deep-seated gravitational slope deformation
remote sensing
interferometric synthetic aperture radar
geophysical time series analysis
Alaska
description We analyze the sensitivity of a large (area extent ∼3 km 2 ), deep-seated gravitational slope deformation (Fels slide, Alaska Range) to three specific drivers: (i) liquid surface water input from ERA-5 reanalysis snow melt and rainfall; (ii) locally projected seismic activity of Alaskan earthquakes; and (iii) lowering of Fels Glacier at the slide toe estimated from topographic data. A surface displacement map-series is derived from 1991 to 2016 spaceborne multi-sensor InSAR data (ERS, RADARSAT-1/2, ALOS, TerraSAR-X) using adaptive demodulation to unwrap interferograms of variable spatial resolution and quality. On this series we use independent component analysis (ICA) to uncover five displacement patterns that map to independently moving domains of the slide and then correlate the corresponding temporal pattern intensities with the suspected drivers. We find significant sub-annual correlation between displacement pattern intensities and seasonal water input variations. The correlation can be optimized, for each ICA pattern, by choosing appropriate values of temporal smoothing and lag to create depth-propagated versions of the water input driver. Lag time results ranging from one to 3 weeks relate to shallower and deeper propagations of water input, driving the different deformation patterns. For two of the deformation patterns, seasonal sensitivity to water input was strongly amplified by the 2002 M w 7.9 Denali earthquake. Sensitivity of these patterns remained high for 4 years until abruptly dropping to below pre-earthquake values, which suggests a highly non-linear modulation by the seismic driver. Other deformation patterns show a steady intensity increase that appears linked to the deglaciation driver. Despite these observations, the inter-annual variations in ICA pattern intensities show no clear predictability by individual drivers or driver combinations. This suggests that the mechanical and hydraulic evolution of the slide, especially after damaging events such as earthquakes or heavy rainfall, is a ...
format Still Image
author Bernhard Rabus
Jeanine Engelbrecht
John J. Clague
Davide Donati
Doug Stead
Mirko Francioni
author_facet Bernhard Rabus
Jeanine Engelbrecht
John J. Clague
Davide Donati
Doug Stead
Mirko Francioni
author_sort Bernhard Rabus
title Image1_Response of a large deep-seated gravitational slope deformation to meteorological, seismic, and deglaciation drivers as measured by InSAR.pdf
title_short Image1_Response of a large deep-seated gravitational slope deformation to meteorological, seismic, and deglaciation drivers as measured by InSAR.pdf
title_full Image1_Response of a large deep-seated gravitational slope deformation to meteorological, seismic, and deglaciation drivers as measured by InSAR.pdf
title_fullStr Image1_Response of a large deep-seated gravitational slope deformation to meteorological, seismic, and deglaciation drivers as measured by InSAR.pdf
title_full_unstemmed Image1_Response of a large deep-seated gravitational slope deformation to meteorological, seismic, and deglaciation drivers as measured by InSAR.pdf
title_sort image1_response of a large deep-seated gravitational slope deformation to meteorological, seismic, and deglaciation drivers as measured by insar.pdf
publishDate 2022
url https://doi.org/10.3389/feart.2022.918901.s001
https://figshare.com/articles/figure/Image1_Response_of_a_large_deep-seated_gravitational_slope_deformation_to_meteorological_seismic_and_deglaciation_drivers_as_measured_by_InSAR_pdf/21607389
genre alaska range
glacier
Alaska
genre_facet alaska range
glacier
Alaska
op_relation doi:10.3389/feart.2022.918901.s001
https://figshare.com/articles/figure/Image1_Response_of_a_large_deep-seated_gravitational_slope_deformation_to_meteorological_seismic_and_deglaciation_drivers_as_measured_by_InSAR_pdf/21607389
op_rights CC BY 4.0
op_doi https://doi.org/10.3389/feart.2022.918901.s001
_version_ 1810470368827146240

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