TY - JOUR
T1 - The effect of landfast sea ice buttressing on ice dynamic speedup in the Larsen B embayment, Antarctica
AU - Surawy-Stepney, Trystan
AU - Hogg, Anna E.
AU - Cornford, Stephen L.
AU - Wallis, Benjamin J.
AU - Davison, Benjamin J.
AU - Selley, Heather L.
AU - Slater, Ross A. W.
AU - Lie, Elise K.
AU - Jakob, Livia
AU - Ridout, Andrew
AU - Gourmelen, Noel
AU - Freer, Bryony I. D.
AU - Wilson, Sally F.
AU - Shepherd, Andrew
N1 - Funding information: This research has been supported by the European Space Agency (grant nos. ESA-IPL-POE-EF-cb-LE-2019-834, ESA AO/1-10461/20/I-NB, and 4000128095/19/I-DT) and the Natural Environment Research Council (grant nos. NE/T012757/1 and NE/X019071/1)
PY - 2024/3/4
Y1 - 2024/3/4
N2 - We observe the evacuation of 11-year-old landfast sea ice in the Larsen B embayment on the East Antarctic Peninsula in January 2022, which was in part triggered by warm atmospheric conditions and strong offshore winds. This evacuation of sea ice was closely followed by major changes in the calving behaviour and dynamics of a subset of the ocean-terminating glaciers in the region. We show using satellite measurements that, following a decade of gradual slow-down, Hektoria, Green, and Crane glaciers sped up by approximately 20 %–50 % between February and the end of 2022, each increasing in speed by more than 100 m a−1. Circumstantially, this is attributable to their transition into tidewater glaciers following the loss of their ice shelves after the landfast sea ice evacuation. However, a question remains as to whether the landfast sea ice could have influenced the dynamics of these glaciers, or the stability of their ice shelves, through a buttressing effect akin to that of confined ice shelves on grounded ice streams. We show, with a series of diagnostic modelling experiments, that direct landfast sea ice buttressing had a negligible impact on the dynamics of the grounded ice streams. Furthermore, we suggest that the loss of landfast sea ice buttressing could have impacted the dynamics of the rheologically weak ice shelves, in turn diminishing their stability over time; however, the accompanying shifts in the distributions of resistive stress within the ice shelves would have been minor. This indicates that this loss of buttressing by landfast sea ice is likely to have been a secondary process in the ice shelf disaggregation compared to, for example, increased ocean swell or the drivers of the initial landfast sea ice disintegration.
AB - We observe the evacuation of 11-year-old landfast sea ice in the Larsen B embayment on the East Antarctic Peninsula in January 2022, which was in part triggered by warm atmospheric conditions and strong offshore winds. This evacuation of sea ice was closely followed by major changes in the calving behaviour and dynamics of a subset of the ocean-terminating glaciers in the region. We show using satellite measurements that, following a decade of gradual slow-down, Hektoria, Green, and Crane glaciers sped up by approximately 20 %–50 % between February and the end of 2022, each increasing in speed by more than 100 m a−1. Circumstantially, this is attributable to their transition into tidewater glaciers following the loss of their ice shelves after the landfast sea ice evacuation. However, a question remains as to whether the landfast sea ice could have influenced the dynamics of these glaciers, or the stability of their ice shelves, through a buttressing effect akin to that of confined ice shelves on grounded ice streams. We show, with a series of diagnostic modelling experiments, that direct landfast sea ice buttressing had a negligible impact on the dynamics of the grounded ice streams. Furthermore, we suggest that the loss of landfast sea ice buttressing could have impacted the dynamics of the rheologically weak ice shelves, in turn diminishing their stability over time; however, the accompanying shifts in the distributions of resistive stress within the ice shelves would have been minor. This indicates that this loss of buttressing by landfast sea ice is likely to have been a secondary process in the ice shelf disaggregation compared to, for example, increased ocean swell or the drivers of the initial landfast sea ice disintegration.
UR - http://www.scopus.com/inward/record.url?scp=85186693573&partnerID=8YFLogxK
U2 - 10.5194/tc-18-977-2024
DO - 10.5194/tc-18-977-2024
M3 - Article
SN - 1994-0424
VL - 18
SP - 977
EP - 993
JO - The Cryosphere
JF - The Cryosphere
IS - 3
ER -