Self‐Entrainment Motion of a Slow‐Moving Landslide Inferred From Landsat‐8 Time Series

Self‐Entrainment Motion of a Slow‐Moving Landslide Inferred From Landsat‐8 Time Series

In mountainous environments, slow‐moving landslides (velocities <100 m/year) are a major concern for local populations. Rainfall is often the dominant forcing, and often result in major changes in kinematics which can mask smaller signals related to internal forcings. We focus here on a major (&g...

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Bibliographic Details
Published in:Journal of geophysical research. Earth surface Vol. 124; no. 5; pp. 1201 - 1216
Main Authors: Lacroix, Pascal, Araujo, Gael, Hollingsworth, James, Taipe, Edu
Format: Journal Article
Language:English
Published: Washington Blackwell Publishing Ltd 01-05-2019
American Geophysical Union/Wiley
Subjects:
Acceleration
Arid environments
Arid zones
Aridity
Collapse
Desert environments
Earth Sciences
Entrainment
Geophysics
Global navigation satellite system
Ground motion
image correlation
Kinematics
Landsat
Landsat satellites
Landsat‐8
landslide
Landslides
Local population
Navigation
Navigation satellites
Navigation systems
Navigational satellites
Noise reduction
Rain
Rainfall
Remote sensing
retrogression
Satellite imagery
Sciences of the Universe
Tectonics
Time series
Topography (geology)
validation
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Summary:In mountainous environments, slow‐moving landslides (velocities <100 m/year) are a major concern for local populations. Rainfall is often the dominant forcing, and often result in major changes in kinematics which can mask smaller signals related to internal forcings. We focus here on a major (>40 Mm3) slow‐moving landslide in the desert of southern Peru and take advantage of this arid environment to study the internal processes affecting landslide kinematics. We first estimate the ground displacement from time series analysis of Landsat‐8 images, spanning a 5.7‐year period. Systematic artifacts in the optical time series are shown to correlate with topography, as well as vary seasonally. We apply a novel procedure for correcting these artifacts, which significantly reduces noise in the resulting time series, thereby allowing us to precisely resolve landslide displacements. We find landslide velocities of up to 35 m/year, with complex nonlinear interannual pattern, including a period of rapid acceleration. We validate our optically derived time series using Global Navigation Satellite System field measurements and find uncertainties (root‐mean‐square error) on the moving mass of 1.12 to 1.55 m. Sudden acceleration of the landslide body after March 2016 may originate from a mass collapse due to retrogression of the headscarp. By coupling sparse 3‐D Global Navigation Satellite System measurements with dense 2‐D optical time series data, we show that the headscarp retrogression acts like a wedge, resulting in domino‐like tilting of the downward blocks, and accelerates basal sliding over 2 years. These observations reveal that the dynamics of this retrogressive landslide are predominantly controlled by sediment supply and that succession of retrogressive and advancing motions is a self‐entrainment process. Key Points Landsat‐8 images are used to measure a 5.7‐year‐long time series of displacement over a slow‐moving landslide A seasonal artifact in the Landsat‐8 images caused by illumination effects in steep topography is identified and corrected A retrogression of the landslide headscarp generates tilting and acceleration of the downward landslide mass
ISSN:2169-9003
2169-9011
DOI:10.1029/2018JF004920