EGU24-11300, updated on 09 Mar 2024
https://doi.org/10.5194/egusphere-egu24-11300
EGU General Assembly 2024
© Author(s) 2024. This work is distributed under
the Creative Commons Attribution 4.0 License.

Icequakes beneath Thwaites Glacier eastern shear margin 

Emma C. Smith1, Ronan Agnew2, Adam D. Booth1, Poul Christoffersen3, Eliza J. Dawson4, Lucia Gonzalez5, Marianne Karplus5, Daniel F. May4, Nori Nakata6, Andrew Pretorius1, Paul Summers4, Slawek Tulaczyk7, Stephen Vietch10, Jake Walter8, and Tun Jan Young9
Emma C. Smith et al.
  • 1University of Leeds, School of Earth and Environment, Leeds, UK (e.c.smith1@leeds.ac.uk)
  • 2British Antarctic Survey, Cambridge, UK
  • 3University of Tasmania, IMAS, Hobart, Tasmania, Australia
  • 4Stanford University, Department of Geophysics, Stanford, California, USA
  • 5University of Texas at El Paso, Department of Earth, Environmental, and Resource Sciences, El Paso, Texas, USA 
  • 6Massachusetts Institute of Technology, Department of Earth, Atmospheric and Planetary Sciences, Boston, MA, USA
  • 7University of California Santa Cruz, Earth & Planetary Sciences Department, Santa Cruz, California, USA
  • 8University of Oklahoma, School of Geosciences, Oklahoma City, Oklahoma, USA
  • 9University of St Andrews, School of Geography and Sustainable Development, St Andrews, UK
  • 10Earthscope Consortium, New Mexico Tech, Socorro, New Mexico, USA

The stability of Thwaites Glacier, the second largest marine ice stream in West Antarctica, is a major source of uncertainty in future predictions of global sea level rise. Critical to understanding the stability of Thwaites Glacier, is understanding the dynamics of the shear margins, which provide important lateral resistance that counters basal weakening associated with ice flow acceleration and forcing at the grounding line. The eastern shear margin of Thwaites Glacier is of interest as it is poorly topographically constrained, meaning it could migrate rapidly, causing further ice flow acceleration and drawing a larger volume of ice into the fast-flowing ice stream.  

In this study, we present an analysis of ~4000 icequakes, recorded over a two-year-period on a broadband seismic array deployed across the eastern shear margin of Thwaites Glacier. The array consisted of seven three-component seismometers, deployed around a central station in a circle, roughly 10 km in diameter.  We use an automated approach to detect and locate “high-frequency” seismic events (10-90 Hz), the majority of which are concentrated in clusters around the ice-bed interface on the slow-moving side of the shear margin, as opposed to within the ice-stream itself. The event waveforms exhibit clear shear-wave splitting, indicative of the presence of an anisotropic ice fabric, likely formed within the shear margin, which is consistent with published radar studies from the field site. Initial analysis of the split shear-waves suggests that they can be used to better constrain the region's ice fabric, and likely used to infer past shear margin location and assess the future stability of this ice rheology.

How to cite: Smith, E. C., Agnew, R., Booth, A. D., Christoffersen, P., Dawson, E. J., Gonzalez, L., Karplus, M., May, D. F., Nakata, N., Pretorius, A., Summers, P., Tulaczyk, S., Vietch, S., Walter, J., and Young, T. J.: Icequakes beneath Thwaites Glacier eastern shear margin , EGU General Assembly 2024, Vienna, Austria, 14–19 Apr 2024, EGU24-11300, https://doi.org/10.5194/egusphere-egu24-11300, 2024.