Journal of Glaciology (Feb 2020)

Tides modulate crevasse opening prior to a major calving event at Bowdoin Glacier, Northwest Greenland

  • Eef van Dongen,
  • Guillaume Jouvet,
  • Andrea Walter,
  • Joe Todd,
  • Thomas Zwinger,
  • Izumi Asaji,
  • Shin Sugiyama,
  • Fabian Walter,
  • Martin Funk

DOI
https://doi.org/10.1017/jog.2019.89
Journal volume & issue
Vol. 66
pp. 113 – 123

Abstract

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Retreat of calving glaciers worldwide has contributed substantially to sea-level rise in recent decades. Mass loss by calving contributes significantly to the uncertainty of sea-level rise projections. At Bowdoin Glacier, Northwest Greenland, most calving occurs by a few large events resulting from kilometre-scale fractures forming parallel to the calving front. High-resolution terrestrial radar interferometry data of such an event reveal that crevasse opening is fastest at low tide and accelerates during the final 36 h before calving. Using the ice flow model Elmer/Ice, we identify the crevasse water level as a key driver of modelled opening rates. Sea water-level variations in the range of local tidal amplitude (1 m) can reproduce observed opening rate fluctuations, provided crevasse water level is at least 4 m above the low-tide sea level. The accelerated opening rates within the final 36 h before calving can be modelled by additional meltwater input into the crevasse, enhanced ice cliff undercutting by submarine melt, ice damage increase due to tidal cyclic fatigue, crevasse deepening or a combination of these processes. Our results highlight the influence of surface meltwater and tides on crevasse opening leading to major calving events at grounded tidewater glaciers such as Bowdoin.

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