Abstract
Both a decrease of sea ice and an increase of surface meltwater, which may induce ice-flow speedup and frontal collapse, have a significant impact on the stability of the floating ice shelf in Greenland. However, detailed dynamic precursors and drivers prior to a fast-calving process remain unclear due to sparse remote sensing observations. Here, we present a comprehensive investigation on hydrological and kinematic precursors before the calving event on 26 July 2017 of Petermann Glacier in northern Greenland, by jointly using remote sensing observations at high-temporal resolution and an ice-flow model. Time series of ice-flow velocity fields during July 2017 were retrieved with Sentinel-2 observations with a sub-weekly sampling interval. The ice-flow speed quickly reached 30 m/d on 26 July (the day before the calving), which is roughly 10 times quicker than the mean glacier velocity. Additionally, a significant decrease in the radar backscatter coefficient of Sentinel-1 images suggests a rapid transformation from landfast sea ice into open water, associated with a decrease in sea ice extent. Additionally, the area of melt ponds on the floating ice tongue began to increase in mid-May, quickly reached a peak at the end of June and lasted for nearly one month until the calving occurred. We used the ice sheet system model to model the spatial-temporal damage and stress on the floating ice, thereby finding an abnormal stress distribution in a cracked region. It is inferred that this calving event may relate to a weakening of the sea ice, shearing of the tributary glacier, and meltwater infiltrating crevasses.
Highlights
The side of icebergs from the tributary glacier developed one band of ice bend existing in front left side of icebergs from the tributary glacier developed one band of ice bend existing in of theoffracture, and itand suffered fromfrom highhigh lateral shear stress
This paper quantified high spatial-temporal ice flow speeds, sea ice backscatter and melt-water ponds with multi-source remote sensing datasets and calculated the stress and damage of a floating ice tongue using a numerical ice flow model, to understand the precursors and causes for a calving event that occurred in July 2017 at the Petermann
The weakening of landfast sea ice reduces the buttressing force for the glacier terminus as its extent declines, which most directly leads to calving
Summary
Ice shelf calving in Greenland can trigger and/or enhance ice flow acceleration and glacier front retreat [1], which is becoming a crucial factor affecting Greenland’s ice sheet stability [2]. Loss of an ice shelf can reduce resistance to ice flow from a grounded glacier [3,4,5], leading to increased discharge from the ice-sheet interior into the oceans [6,7]. Some observation and modeling investigations suggest that tidewater glaciers are sensitive to both atmospheric and oceanic forcing [8,9,10], the physical processes of the frontal collapse and their responses to warming air and sea temperatures are not fully understood [2]
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