Abstract
Abstract
The Ward Hunt and Milne ice shelves are the present-day remnants of a much larger ice shelf that once fringed the coast of Ellesmere Island, Canada. These ice shelves possess a unique surface morphology consisting of wave-like rolls that run parallel to the shoreline. Setting aside the question of how these rolls originally developed, we consider the impact of this roll morphology on the stability of the ice shelf. In particular, we examine whether periodic variations in ice-shelf thickness and water depth implied by the rolls prevent the excitation of Lamb waves in the ice shelf. Using a hierarchy of numerical models, we find that there are band gaps in the flexural and extensional modes of the ice shelf, implying the existence of frequency ranges that lack wave motion. We show that an ice shelf with rolls is able to reflect waves in these frequency ranges that are incident upon its ice front, thereby mitigating undue stress and calving. We speculate that the roll morphology provides a “fitness” for survival that explains why rolls are observed in the oldest and thickest multiyear sea ice of the Arctic.
Funder
National Science Foundation
Publisher
Cambridge University Press (CUP)
Reference56 articles.
1. Walker, CC , Fricker, HA , Millstein, JD , Miles, B and Trusel, LD (2022) Sustained long-term collapse of Conger-Glenzer Ice Shelf, East Antarctica, Abstract C13B-02 presented at 2022 AGU Fall Meeting, Dec. 12–15.
2. Seismic observations of sea swell on the floating Ross Ice Shelf, Antarctica
3. The reflection of X-rays by crystals;Bragg;Proceedings of the Royal Society of London. Series A, Containing Papers of a Mathematical and Physical Character,1913
4. A millennial-scale record of Arctic Ocean sea ice variability and the demise of the Ellesmere Island ice shelves
5. Ocean-excited plate waves in the Ross and Pine Island Glacier ice shelves