A Framework for Studying Hydrology-Driven Landslide Hazards in Northwestern US Using Satellite InSAR, Precipitation and Soil Moisture Observations: Early Results and Future Directions

Lü, Zhong; Kim, Jin‐Woo

doi:10.3390/geohazards2020002

Cited by 14 publications

(9 citation statements)

References 82 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Thus, lidar can provide more accurate values of cumulative displacement in this environment, which allows for average velocity calculations. Additionally, lidar provides accurate downslope (i.e., 3D) displacement values, whereas LOS displacement values provided by InSAR cannot be deconvolved to understand the horizontal and vertical components of motion without considering images in the opposite viewing mode (e.g., ascending vs. descending; Lu & Kim, 2021). Thus, a direct comparison in displacement magnitude cannot be made between these two techniques, nor can we compare pixel to pixel between methods due to both coherence loss in InSAR images (e.g., the Kite, Figure 7) and limited features that can be used for feature tracking in lidar (Figure 6).…”

Section: Discussionmentioning

confidence: 99%

Kinematic Evolution of a Large Paraglacial Landslide in the Barry Arm Fjord of Alaska

Schaefer,

Coe,

Wikstrom Jones

et al. 2023

JGR Earth Surface

View full text Add to dashboard Cite

Our warming climate is adversely affecting cryospheric landscapes via glacial retreat, permafrost degradation, and associated slope destabilization. In Prince William Sound, Alaska, the rapid retreat of Barry Glacier has destabilized the slopes flanking the glacier, resulting in numerous landslides. The largest of these landslides (∼500 Mm3 in volume) is more than 2 km wide and has the potential to generate a tsunami that could affect nearby recreationists, marine traffic, infrastructure, natural and cultural resources, and the community of Whittier, located 60 km from the landslide. Here, we combine landslide structural and kinematic element mapping with data acquired from bi‐yearly airborne lidar, multi‐week satellite‐based synthetic aperture radar (SAR), sub‐hourly ground‐based SAR, and seismic monitoring from 2020 to 2022 to characterize this landslide and examine its evolution. While some methods serve as a snapshot in time that is a culmination of events, others emphasize the ever‐evolving nature of the landslide and associated hazards. Four major kinematic elements define the overall structure of the landslide, which vary in deformation type and rate, from creep (5 mm per day over several months) to episodic movement (2 m in 30 days) and landslide‐wide to localized events. In some areas of the landslide, short‐term deformation deviates from structures formed by cumulative movement, implying structural and kinematic evolution associated with glacier retreat. These insights are important for assessing landslide hazards and hazard evolution for large, slow‐moving bedrock landslides in actively deglaciating environments.

show abstract

Section: Discussionmentioning

confidence: 99%

Kinematic Evolution of a Large Paraglacial Landslide in the Barry Arm Fjord of Alaska

Schaefer,

Coe,

Wikstrom Jones

et al. 2023

JGR Earth Surface

View full text Add to dashboard Cite

show abstract

“…Ground vegetation and surface modification (e.g., erosion, deposition, and soil moisture change) are the primary factors that cause decorrelation of SAR images, consequently decreasing the accuracy of InSAR measurements for monitoring landslide displacements in a regional scale (e.g., Lu & Kim, 2021; Xu, George, et al., 2021; Xu, Lu, et al., 2021). Such impacts are common in global climate regions abundant in precipitation, such as the Tropical Wet, Tropical Wet and Dry, Mediterranean, Marine West Coast, Humid Subtropical, and Humid Continental climates (Peel et al., 2007).…”

Section: Discussionmentioning

confidence: 99%

Kinematics of Irrigation‐Induced Landslides in a Washington Desert: Impacts of Basal Geometry

Lü

Leshchinsky

2022

JGR Earth Surface

Self Cite

View full text Add to dashboard Cite

Landslides are often considered to be a natural hazard that frequently occurs in mountainous, precipitation-abundant regions worldwide; however, they can also occur in dry climates resulting from anthropogenic infuences, such as irrigation farming. Generally less affected by precipitation, landslides in arid regions are ideal for examining impacts of non-precipitation controls on landslide motion, such as basal geometry. Here, we focused on 25 large, irrigation-triggered, slow-moving and catastrophic landslides that occurred in a desert valley near Hanford, Washington along the Columbia River. Optical images in submeter resolution from 1996 to 2020 and Sentinel-1 interferometric synthetic aperture radar (InSAR) deformation measurements from 2016 to 2020 were utilized to map 12 catastrophic landslides and obtain time-series deformation of 13 actively slow-moving landslide complexes. Our results show that the catastrophic landslides usually completed their life cycle from initiation to final deposition within minutes to days, whereas the slowmoving ones have lasted approximately 40 years, exhibiting rapid acceleration and a subsequent deceleration period that is almost 12 times longer. Though varying in rates, both types of landslides facilitate sediment transport into the Columbia River, which is of concern for aquatic habitats. Motion dynamics of the four riverside, slow-moving landslides were strongly modulated by the Columbia River height subject to seasonal dam water release, whereas the eight river-distant landslides primarily respond to the infiltrated irrigation water from the farmlands. We observed an apparent "early deceleration" phenomenon for the riverside Locke landslide, where the landslide starts to decelerate despite the threshold groundwater conditions being exceeded. We interpret that the early decelerations result from the forced water circulation near the basalsurface asperities, because river bathymetry data suggest that basal surfaces of the Locke landslide (originally the Columbia River bed) are highly irregular. This interpretation was also supported by numerical simulations, which show that incorporating the forced water circulation may help accurately predict the InSAR-observed maximum velocity and the timing of deceleration. Additionally, our analyses of basal profiles of 10 slowmoving and catastrophic landslides in the study region reveal that basal geometry could impart a bifurcation between slow and catastrophic landslide movements. Gentle basal surfaces are more likely associated with large, slow-moving landslides, whereas steep ones are often involved with relatively small, catastrophic landslides due to rapid kinetic energy gains while moving downslope. In general, the examined impacts of basal geometry in this study are widely applicable to natural landslides worldwide for their kinematics characterization and forecasting.Plain Language Summary Landslides in arid regions are barely affected by ground rainfall and therefore provide a unique opportunity to study how other factors, su...

show abstract

“…This method can correct baseline-induced artifacts, digital elevation model (DEM) errors, and atmospheric disturbances through spatiotemporal regression and filtering. This permits the creation of time series of subtle (on the order of 10s of millimeters) ground deformation (Ferretti and others, 2001;Hooper and others, 2004;Hooper, 2008;Lu and Kim, 2021) and is effective in identifying landslides in paraglacial regions (Kim and others, 2022).…”

Section: Persistent Scatterer Interferometric Synthetic Aperture Radarmentioning

confidence: 99%

“…Landslide velocity and changes in velocity also serve as critical inputs in landslide hazard assessments (for example, Hermanns and others, 2013). On a regional scale, satellite remote sensing that identifies deformation (for example, methods using synthetic aperture radar [SAR] data; Lu and Kim 2021;Kim and others, 2022) or detects change associated with movement (for example, methods using multispectral data; Nichol and Wong, 2005;Ramos-Bernal and others, 2018) can provide the spatial and temporal resolution required to better understand landslide initiation, kinematics, and triggering conditions.…”

Section: Introductionmentioning

confidence: 99%

Satellite Interferometry Landslide Detection and Preliminary Tsunamigenic Plausibility Assessment in Prince William Sound, Southcentral Alaska

Schaefer,

Kim,

Staley

et al. 2024

Open-File Report

Self Cite

View full text Add to dashboard Cite

For more information on the USGS-the Federal source for science about the Earth, its natural and living resources, natural hazards, and the environment-visit https://www.usgs.gov or call 1-888-392-8545.For an overview of USGS information products, including maps, imagery, and publications, visit https://store.usgs.gov/ or contact the store at 1-888-275-8747.Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government.Although this information product, for the most part, is in the public domain, it also may contain copyrighted materials as noted in the text. Permission to reproduce copyrighted items must be secured from the copyright owner.

show abstract

A Framework for Studying Hydrology-Driven Landslide Hazards in Northwestern US Using Satellite InSAR, Precipitation and Soil Moisture Observations: Early Results and Future Directions

Cited by 14 publications

References 82 publications

Kinematic Evolution of a Large Paraglacial Landslide in the Barry Arm Fjord of Alaska

Kinematic Evolution of a Large Paraglacial Landslide in the Barry Arm Fjord of Alaska

Kinematics of Irrigation‐Induced Landslides in a Washington Desert: Impacts of Basal Geometry

Satellite Interferometry Landslide Detection and Preliminary Tsunamigenic Plausibility Assessment in Prince William Sound, Southcentral Alaska

Contact Info

Product

Resources

About