DataSheet2_Evaluation of Remote Mapping Techniques for Earthquake-Triggered Landslide Inventories in an Urban Subarctic Environment: A Case Study of the 2018 Anchorage, Alaska Earthquake.docx

Earthquake-induced landslide inventories can be generated using field observations but doing so can be challenging if the affected landscape is large or inaccessible after an earthquake. Remote sensing data can be used to help overcome these limitations. The effectiveness of remotely sensed data to...

Full description

Bibliographic Details
Main Authors: S. N. Martinez, L. N. Schaefer, K. E. Allstadt, E. M. Thompson
Format: Dataset
Language:unknown
Published: 2021
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
NDVI
amplitude change detection
DEM differencing
image thresholding
Google Earth Engine (GEE)
urban
Anchorage
Subarctic
Alaska
Online Access:https://doi.org/10.3389/feart.2021.673137.s002
https://figshare.com/articles/dataset/DataSheet2_Evaluation_of_Remote_Mapping_Techniques_for_Earthquake-Triggered_Landslide_Inventories_in_an_Urban_Subarctic_Environment_A_Case_Study_of_the_2018_Anchorage_Alaska_Earthquake_docx/14778423
id ftfrontimediafig:oai:figshare.com:article/14778423
record_format openpolar
spelling ftfrontimediafig:oai:figshare.com:article/14778423 2023-05-15T18:28:40+02:00 DataSheet2_Evaluation of Remote Mapping Techniques for Earthquake-Triggered Landslide Inventories in an Urban Subarctic Environment: A Case Study of the 2018 Anchorage, Alaska Earthquake.docx S. N. Martinez L. N. Schaefer K. E. Allstadt E. M. Thompson 2021-06-14T09:05:37Z https://doi.org/10.3389/feart.2021.673137.s002 https://figshare.com/articles/dataset/DataSheet2_Evaluation_of_Remote_Mapping_Techniques_for_Earthquake-Triggered_Landslide_Inventories_in_an_Urban_Subarctic_Environment_A_Case_Study_of_the_2018_Anchorage_Alaska_Earthquake_docx/14778423 unknown doi:10.3389/feart.2021.673137.s002 https://figshare.com/articles/dataset/DataSheet2_Evaluation_of_Remote_Mapping_Techniques_for_Earthquake-Triggered_Landslide_Inventories_in_an_Urban_Subarctic_Environment_A_Case_Study_of_the_2018_Anchorage_Alaska_Earthquake_docx/14778423 CC BY 4.0 CC-BY 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 NDVI amplitude change detection DEM differencing image thresholding Google Earth Engine (GEE) urban Dataset 2021 ftfrontimediafig https://doi.org/10.3389/feart.2021.673137.s002 2021-06-16T22:59:27Z Earthquake-induced landslide inventories can be generated using field observations but doing so can be challenging if the affected landscape is large or inaccessible after an earthquake. Remote sensing data can be used to help overcome these limitations. The effectiveness of remotely sensed data to produce landslide inventories, however, is dependent on a variety of factors, such as the extent of coverage, timing, and data quality, as well as environmental factors such as atmospheric interference (e.g., clouds, water vapor) or snow and vegetation cover. With these challenges in mind, we use a combination of field observations and remote sensing data from multispectral, light detection and ranging (lidar), and synthetic aperture radar (SAR) sensors to produce a ground failure inventory for the urban areas affected by the 2018 magnitude (M w ) 7.1 Anchorage, Alaska earthquake. The earthquake occurred during late November at high latitude (∼61°N), and the lack of sunlight, persistent cloud cover, and snow cover that occurred after the earthquake made remote mapping challenging for this event. Despite these challenges, 43 landslides were manually mapped and classified using a combination of the datasets mentioned previously. Using this manually compiled inventory, we investigate the individual performance and reliability of three remote sensing techniques in this environment not typically hospitable to remotely sensed mapping. We found that differencing pre- and post-event normalized difference vegetation index maps and lidar worked best for identifying soil slumps and rapid soil flows, but not as well for small soil slides, soil block slides and rock falls. The SAR-based methods did not work well for identifying any landslide types because of high noise levels likely related to snow. Some landslides, especially those that resulted in minor surface displacement, were identifiable only from the field observations. This work highlights the importance of the rapid collection of field observations and provides guidance ... Dataset Subarctic Alaska Frontiers: Figshare Anchorage
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
NDVI
amplitude change detection
DEM differencing
image thresholding
Google Earth Engine (GEE)
urban
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
NDVI
amplitude change detection
DEM differencing
image thresholding
Google Earth Engine (GEE)
urban
S. N. Martinez
L. N. Schaefer
K. E. Allstadt
E. M. Thompson
DataSheet2_Evaluation of Remote Mapping Techniques for Earthquake-Triggered Landslide Inventories in an Urban Subarctic Environment: A Case Study of the 2018 Anchorage, Alaska Earthquake.docx
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
NDVI
amplitude change detection
DEM differencing
image thresholding
Google Earth Engine (GEE)
urban
description Earthquake-induced landslide inventories can be generated using field observations but doing so can be challenging if the affected landscape is large or inaccessible after an earthquake. Remote sensing data can be used to help overcome these limitations. The effectiveness of remotely sensed data to produce landslide inventories, however, is dependent on a variety of factors, such as the extent of coverage, timing, and data quality, as well as environmental factors such as atmospheric interference (e.g., clouds, water vapor) or snow and vegetation cover. With these challenges in mind, we use a combination of field observations and remote sensing data from multispectral, light detection and ranging (lidar), and synthetic aperture radar (SAR) sensors to produce a ground failure inventory for the urban areas affected by the 2018 magnitude (M w ) 7.1 Anchorage, Alaska earthquake. The earthquake occurred during late November at high latitude (∼61°N), and the lack of sunlight, persistent cloud cover, and snow cover that occurred after the earthquake made remote mapping challenging for this event. Despite these challenges, 43 landslides were manually mapped and classified using a combination of the datasets mentioned previously. Using this manually compiled inventory, we investigate the individual performance and reliability of three remote sensing techniques in this environment not typically hospitable to remotely sensed mapping. We found that differencing pre- and post-event normalized difference vegetation index maps and lidar worked best for identifying soil slumps and rapid soil flows, but not as well for small soil slides, soil block slides and rock falls. The SAR-based methods did not work well for identifying any landslide types because of high noise levels likely related to snow. Some landslides, especially those that resulted in minor surface displacement, were identifiable only from the field observations. This work highlights the importance of the rapid collection of field observations and provides guidance ...
format Dataset
author S. N. Martinez
L. N. Schaefer
K. E. Allstadt
E. M. Thompson
author_facet S. N. Martinez
L. N. Schaefer
K. E. Allstadt
E. M. Thompson
author_sort S. N. Martinez
title DataSheet2_Evaluation of Remote Mapping Techniques for Earthquake-Triggered Landslide Inventories in an Urban Subarctic Environment: A Case Study of the 2018 Anchorage, Alaska Earthquake.docx
title_short DataSheet2_Evaluation of Remote Mapping Techniques for Earthquake-Triggered Landslide Inventories in an Urban Subarctic Environment: A Case Study of the 2018 Anchorage, Alaska Earthquake.docx
title_full DataSheet2_Evaluation of Remote Mapping Techniques for Earthquake-Triggered Landslide Inventories in an Urban Subarctic Environment: A Case Study of the 2018 Anchorage, Alaska Earthquake.docx
title_fullStr DataSheet2_Evaluation of Remote Mapping Techniques for Earthquake-Triggered Landslide Inventories in an Urban Subarctic Environment: A Case Study of the 2018 Anchorage, Alaska Earthquake.docx
title_full_unstemmed DataSheet2_Evaluation of Remote Mapping Techniques for Earthquake-Triggered Landslide Inventories in an Urban Subarctic Environment: A Case Study of the 2018 Anchorage, Alaska Earthquake.docx
title_sort datasheet2_evaluation of remote mapping techniques for earthquake-triggered landslide inventories in an urban subarctic environment: a case study of the 2018 anchorage, alaska earthquake.docx
publishDate 2021
url https://doi.org/10.3389/feart.2021.673137.s002
https://figshare.com/articles/dataset/DataSheet2_Evaluation_of_Remote_Mapping_Techniques_for_Earthquake-Triggered_Landslide_Inventories_in_an_Urban_Subarctic_Environment_A_Case_Study_of_the_2018_Anchorage_Alaska_Earthquake_docx/14778423
geographic Anchorage
geographic_facet Anchorage
genre Subarctic
Alaska
genre_facet Subarctic
Alaska
op_relation doi:10.3389/feart.2021.673137.s002
https://figshare.com/articles/dataset/DataSheet2_Evaluation_of_Remote_Mapping_Techniques_for_Earthquake-Triggered_Landslide_Inventories_in_an_Urban_Subarctic_Environment_A_Case_Study_of_the_2018_Anchorage_Alaska_Earthquake_docx/14778423
op_rights CC BY 4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.3389/feart.2021.673137.s002
_version_ 1766211221282881536

Similar Items