Tracking the Cracking: A Holistic Analysis of Rapid Ice Shelf Fracture Using Seismology, Geodesy, and Satellite Imagery on the Pine Island Glacier Ice Shelf, West Antarctica

S D Olinger; B P Lipovsky; M A Denolle; B W Crowell

doi:10.1029/2021GL097604

Tracking the Cracking: A Holistic Analysis of Rapid Ice Shelf Fracture Using Seismology, Geodesy, and Satellite Imagery on the Pine Island Glacier Ice Shelf, West Antarctica

Geophys Res Lett. 2022 May 28;49(10):e2021GL097604. doi: 10.1029/2021GL097604. Epub 2022 May 20.

Authors

S D Olinger^{1

2}, B P Lipovsky², M A Denolle², B W Crowell²

Affiliations

¹ Department of Earth and Planetary Sciences Harvard University Cambridge MA USA.
² Department of Earth and Space Sciences University of Washington Seattle WA USA.

Abstract

Ice shelves regulate the stability of marine ice sheets. We track fractures on Pine Island Glacier, a quickly accelerating glacier in West Antarctica that contributes more to sea level rise than any other glacier. Using an on-ice seismic network deployed from 2012 to 2014, we catalog icequakes that dominantly consist of flexural gravity waves. Icequakes occur near the rift tip and in two distinct areas of the shear margin, and TerraSAR-X imagery shows significant fracture in each source region. Rift-tip icequakes increase with ice speed, linking rift fracture to glaciological stresses and/or localized thinning. Using a simple flexural gravity wave model, we deconvolve wave propagation effects to estimate icequake source durations of 19.5-50.0 s and transient loads of 3.8-14.0 kPa corresponding to 4.3-15.9 m of crevasse growth per icequake. These long-source durations suggest that water flow may limit the rate of crevasse opening.

Keywords: Pine Island Glacier; calving; ice shelf fracture; rifting.