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A Tale of Two Ice Shelves: Contrasting Behavior During the Regional Destabilization of the Dotson-Crosson Ice Shelf System, West Antarctica
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  • Christian T. Wild,
  • Tiago Segabinazzi Dotto,
  • Karen E. Alley,
  • Gabriela Collao-Barrios,
  • Atsuhiro Muto,
  • Rob A. Hall,
  • Martin Truffer,
  • Ted A. Scambos,
  • Karen J. Heywood,
  • Erin C. Pettit
Christian T. Wild
Oregon State University, Oregon State University, Oregon State University

Corresponding Author:[email protected]

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Tiago Segabinazzi Dotto
University of East Anglia, University of East Anglia, University of East Anglia
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Karen E. Alley
University of Manitoba, University of Manitoba, University of Manitoba
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Gabriela Collao-Barrios
US National Snow and Ice Data Center, US National Snow and Ice Data Center, US National Snow and Ice Data Center
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Atsuhiro Muto
Temple University, Temple University, Temple University
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Rob A. Hall
University of East Anglia, University of East Anglia, University of East Anglia
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Martin Truffer
University of Alaska Fairbanks, University of Alaska Fairbanks, University of Alaska Fairbanks
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Ted A. Scambos
US National Snow and Ice Data Center, US National Snow and Ice Data Center, US National Snow and Ice Data Center
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Karen J. Heywood
University of East Anglia, University of East Anglia, University of East Anglia
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Erin C. Pettit
Oregon State University, Oregon State University, Oregon State University
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Abstract

The Dotson Ice Shelf has resisted acceleration and ice-front retreat despite high basal-melt rates and rapid disaggregation of the neighboring Crosson Ice Shelf. Because of this lack of acceleration, previous studies have assumed that Dotson is stable. Here we show clear evidence of Dotson's destabilization as it decelerates, contrary to the common assumption that ice-flow deceleration is synonymous with stability. Ungrounding of a series of pinning points initiated acceleration in the Upper Dotson in the early 2000s, which subsequently slowed ice flow in the Lower Dotson. Discharge from the tributary Kohler Glacier into Crosson increased, but non-proportionally. Using ICESat and ICESat-2 altimetry data we show that ungrounding of the remaining pinning points is linked to a tripling in basal melt rates between 2006-2016 and 2016-2020. Basal melt rates on Crosson doubled over the same period. The higher basal melt at Lower Dotson is consistent with the cyclonic ocean circulation in the Dotson cavity, which tends to lift isopycnals and allow warmer deep water to interact with the ice. Given current surface-lowering rates, we estimate that several remaining pinning points in the Upper Dotson will unground within one to three decades. The grounding line of Kohler Glacier will retreat past a bathymetric saddle by the late 2030s and merge into the Smith West Glacier catchment, raising concern that reconfiguration of regional ice-flow dynamics and new pathways for the intrusion of warm modified Circumpolar Deep Water could further accelerate grounding-line retreat in the Dotson-Crosson Ice Shelf System.