High Mountain Asia is impacted by extreme monsoonal rainfall that triggers landslides in large proportions relative to global distributions, resulting in substantial human impacts and damage to infrastructure each year. Previous landslide research has qualitatively estimated how patterns in landslide activity may change based on climate change scenarios. We present the first quantitative view of potential modulation in future landslide activity over the High Mountain Asia region leveraging a new landslide hazard model and precipitation data from satellite and Global Climate Model sources. In doing so, we find that the rate of increase in landslide activity at the end of the century is expected to be greatest over areas covered by current glaciers and glacial lakes, potentially exacerbating the impacts of cascading hazards on populations downstream. This work demonstrates the potential of Global Climate Models and satellite-based precipitation estimates to characterize landslide hazards at time scales affected by climate change.

Kirschbaum D., Kapnick S.B., Stanley T., Pascale S. (2020). Changes in Extreme Precipitation and Landslides Over High Mountain Asia. GEOPHYSICAL RESEARCH LETTERS, 47(4), 1-9 [10.1029/2019GL085347].

Changes in Extreme Precipitation and Landslides Over High Mountain Asia

Pascale S.
2020

Abstract

High Mountain Asia is impacted by extreme monsoonal rainfall that triggers landslides in large proportions relative to global distributions, resulting in substantial human impacts and damage to infrastructure each year. Previous landslide research has qualitatively estimated how patterns in landslide activity may change based on climate change scenarios. We present the first quantitative view of potential modulation in future landslide activity over the High Mountain Asia region leveraging a new landslide hazard model and precipitation data from satellite and Global Climate Model sources. In doing so, we find that the rate of increase in landslide activity at the end of the century is expected to be greatest over areas covered by current glaciers and glacial lakes, potentially exacerbating the impacts of cascading hazards on populations downstream. This work demonstrates the potential of Global Climate Models and satellite-based precipitation estimates to characterize landslide hazards at time scales affected by climate change.
2020
Kirschbaum D., Kapnick S.B., Stanley T., Pascale S. (2020). Changes in Extreme Precipitation and Landslides Over High Mountain Asia. GEOPHYSICAL RESEARCH LETTERS, 47(4), 1-9 [10.1029/2019GL085347].
Kirschbaum D.; Kapnick S.B.; Stanley T.; Pascale S.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11585/850685
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