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1. Seismic travel time inversion code from: Geophysical evidence of tectonic structures beneath Thwaites Glacier, West Antarctica: influence on glacier dynamics

   https://doi.org/10.5281/zenodo.15230758  

   Borthwick, Louise; Muto, Atsuhiro; Anandakrishnan, Sridhar; Tinto, Kirsty; Agnew, Ronan; Brisbourne, Alex; Schlegel, Rebecca; killingbeck, siobhan; Kulessa, Bernd; Alley, Richard; et al (April 2025, Zenodo)

   Seismic travel time inversion code from: Geophysical evidence of tectonic structures beneath Thwaites Glacier, West Antarctica: influence on glacier dynamics. Submitted to Journal of Geophysical Research: Solid Earth 

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2. Results from: Geophysical evidence of tectonic structures beneath Thwaites Glacier, West Antarctica: influence on glacier dynamics

   https://doi.org/10.5281/zenodo.15236556  

   Borthwick, Louise; Muto, Atsuhiro; Anandakrishnan, Sridhar; Tinto, Kirsty; Agnew, Ronan; Brisbourne, Alex; Schlegel, Rebecca; killingbeck, siobhan; Kulessa, Bernd; Alley, Richard; et al (April 2025, Zenodo)

   Results from seismic travel time inversion and potential fields modeling in: Geophysical evidence of tectonic structures beneath Thwaites Glacier, West Antarctica: influence on glacier dynamics 

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3. Comprehensive Radar Mapping of Malaspina Glacier (Sít' Tlein), Alaska—The World's Largest Piedmont Glacier—Reveals Potential for Instability

   https://doi.org/10.1029/2022JF006898  

   Tober, B. S.; Holt, J. W.; Christoffersen, M. S.; Truffer, M.; Larsen, C. F.; Brinkerhoff, D. J.; Mooneyham, S. A. (March 2023, Journal of Geophysical Research: Earth Surface)

   Abstract Malaspina Glacier, located on the coast of southern Alaska, is the world's largest piedmont glacier. A narrow ice‐cored foreland zone undergoing rapid thermokarst erosion separates the glacier from the relatively warm waters of the Gulf of Alaska. Glacier‐wide thinning rates for Malaspina are greater than 1 m/yr, and previous geophysical investigations indicated that bed elevation exceeds 300 m below sea level in some places. These observations together give rise to the question of glacial stability. To address this question, glacier evolution models are dependent upon detailed observations of Malaspina's subglacial topography. Here, we map 2,000 line‐km of the glacier's bed using airborne radar sounding data collected by NASA's Operation IceBridge. When compared to gridded radar measurements, we find that glaciological models overestimate Malaspina's volume by more than 30%. While we report a mean bed elevation 100 m greater than previous models, we find that Malaspina inhabits a broad basin largely grounded below sea level. Several subglacial channels dissect the glacier's bed: the most prominent of these channels extends at least 35 km up‐glacier from the terminus toward the throat of Seward Glacier. Provided continued foreland erosion, an ice‐ocean connection may promote rapid retreat along these overdeepened subglacial channels, with a global sea‐level rise potential of 1.4 mm. 

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4. Basal conditions of Malaspina Glacier

   https://doi.org/10.7914/sn/3j_2021  

   Truffer, Martin; Larsen, Chris; Fahnestock, Mark (January 2021, International Federation of Digital Seismograph Networks)

   In this active seismic experiment we will collect AVO data at two glacier sites. One is located over a glacier bed high and the other one over a depression. The goals is to use Amplitude vs Offset methods to determine the nature of the subglacial material. A line of 24 geophones will be buried in snow to protect them from wind noise and the line will be accurately surveyed with GPS. A set of 100 shot holes will be drilled into the underlying ice to obtain a large range of offsets, so that amplitudes can be compared over large offset angles. If possible, the data will also be used to find the thickness of a subglacial till layer. The seismic experiment is part of a large geophysical and remote sensing observational program with the goal to provide input data for an ice flow model that will explore possible future scenarios for this large glacier that is very vulnerable to future climate change. In a second experiment we will do attempt to measure the extent of buried ice in the glacier foreland. For this experiment we propose to use 4.5 Hz geophones and we will use a hammer for the active source. This is part of the same NSF funded work. 

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5. Melting of glacier ice enhanced by bursting air bubbles

   https://doi.org/10.1038/s41561-023-01262-8  

   Wengrove, Meagan E.; Pettit, Erin C.; Nash, Jonathan D.; Jackson, Rebecca H.; Skyllingstad, Eric D. (September 2023, Nature Geoscience)

   Abstract Feedbacks between ice melt, glacier flow and ocean circulation can rapidly accelerate ice loss at tidewater glaciers and alter projections of sea-level rise. At the core of these projections is a model for ice melt that neglects the fact that glacier ice contains pressurized bubbles of air due to its formation from compressed snow. Current model estimates can underpredict glacier melt at termini outside the region influenced by the subglacial discharge plume by a factor of 10–100 compared with observations. Here we use laboratory-scale experiments and theoretical arguments to show that the bursting of pressurized bubbles from glacier ice could be a source of this discrepancy. These bubbles eject air into the seawater, delivering additional buoyancy and impulses of turbulent kinetic energy to the boundary layer, accelerating ice melt. We show that real glacier ice melts 2.25 times faster than clear bubble-free ice when driven by natural convection in a laboratory setting. We extend these results to the geophysical scale to show how bubble dynamics contribute to ice melt from tidewater glaciers. Consequently, these results could increase the accuracy of modelled predictions of ice loss to better constrain sea-level rise projections globally. 

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