Abstract:
This dataset contains acoustic impedance misfits between measurements collected on Pine Island Glacier (Brisbourne et al., 2017) and predictions of the Viscous Grain-Shearing theory (Buckingham, 1997, 2000, 2005, 2007). The dataset is presented as netCDF files. The acoustic impedance predictions depend on the effective pressure, which is derived using various basal sliding laws. This link enables the comparison of basal sliding laws within a Bayesian model selection framework (Hank et al., 2025). The posterior probabilities (also included in this dataset) were determined by the authors to infer the most probable basal sliding law.
This work was funded by the GHOST project, a component of the International Thwaites Glacier Collaboration (ITGC). Support from National Science Foundation (NSF: Grant PLR 1738934) and Natural Environment Research Council (NERC: Grant NE/S006672/1), with logistics provided by NSF-U.S. Antarctic Program and NERC-British Antarctic Survey.
Keywords:
Bayesian model selection, ITGC, Pine Island Glacier, acoustic impedance, basal sliding, effective pressure
Hank, K., Arthern, R., & Williams, C. (2025). Acoustic impedance misfits and basal sliding law probabilities for Pine Island Glacier (Version 1.0) [Data set]. NERC EDS UK Polar Data Centre. https://doi.org/10.5285/c560ce43-7aa0-4474-90ed-d4ee5f5768ea
| Access Constraints: | No restrictions apply. |
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| Use Constraints: | Data supplied under Open Government Licence v3.0 http://www.nationalarchives.gov.uk/doc/open-government-licence/version/3/. |
| Creation Date: | 2025-10-31 |
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| Dataset Progress: | Complete |
| Dataset Language: | English |
| ISO Topic Categories: |
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| Parameters: |
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| Personnel: | |
| Name | UK Polar Data Centre |
| Role(s) | Metadata Author |
| Organisation | British Antarctic Survey |
| Name | Kevin Hank |
| Role(s) | Technical Contact, Investigator |
| Organisation | British Antarctic Survey |
| Name | Robert J Arthern |
| Role(s) | Investigator |
| Organisation | British Antarctic Survey |
| Name | C. Rosie Williams |
| Role(s) | Investigator |
| Organisation | British Antarctic Survey |
| Parent Dataset: | N/A |
| Reference: | Arthern, R. J., Hindmarsh, R. C., and Williams, C. R.: Flow speed within the Antarctic ice sheet and its controls inferred from satellite observations, Journal of Geophysical Research: Earth Surface, 120, 1171-1188, https://doi.org/10.1002/2014JF003239, 2015. Brisbourne, A. M., Smith, A. M., Vaughan, D. G., King, E. C., Davies, D., Bingham, R. G., Smith, E. C., Nias, I. J., and Rosier, S. H.: Bed conditions of Pine Island Glacier, West Antarctica, Journal of Geophysical Research: Earth Surface, 122, 419-433, https://doi.org/10.1002/2016JF004033, 2017. Buckingham, M. J. (1997). Theory of acoustic attenuation, dispersion, and pulse propagation in unconsolidated granular materials including marine sediments. The Journal of the Acoustical Society of America, 102(5), 2579-2596. https://doi.org/10.1121/1.420313. Buckingham, M. J. (2000). Wave propagation, stress relaxation, and grain-to-grain shearing in saturated, unconsolidated marine sediments. The Journal of the Acoustical Society of America, 108(6), 2796-2815. https://doi.org/10.1121/1.1322018. Buckingham, M. J.: Compressional and shear wave properties of marine sediments: Comparisons between theory and data, The Journal of the Acoustical Society of America, 117, 137-152, https://doi.org/10.1121/1.1810231, 2005. Buckingham, M. J.: On pore-fluid viscosity and the wave properties of saturated granular materials including marine sediments, The Journal of the Acoustical Society of America, 122, 1486-1501, https://doi.org/10.1121/1.2759167, 2007. Buckingham, M. J.: Analysis of shear-wave attenuation in unconsolidated sands and glass beads, The Journal of the Acoustical Society of America, 136, 2478-2488, https://doi.org/10.1121/1.4896468, 2014. Hank, K., Arthern, R. J., Williams, C. R., Brisbourne, A. M., Smith, A. M., Smith, J. A., Wahlin, A., and Anandakrishnan, S.: The Antarctic Ice Sheet sliding law inferred from seismic observations, EGUsphere, 2025, 1-22, https://doi.org/10.5194/egusphere-2025-764, 2025. |
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| Quality: | Key experiments were repeated with (log-)uniform prior distributions for all parameters to examine the sensitivity to the choice of the prior. Furthermore, experiments with a sub-sampled data set (every 10th acoustic impedance measurement) were carried out. A value of NaN indicates there is no data there. | |
| Lineage/Methodology: | The misfit between measured and predicted acoustic impedance is used to infer the most probable basal sliding law, as described in Hank et al. (2025). This methodology utilizes the dependence of predicted acoustic impedance on effective pressure, as described by the Viscous Grain-Shearing theory (VGS; Buckingham, 1997, 2000, 2005, 2007). The effective pressure is determined based on the basal sliding laws. Usually, these laws are expressed so that basal drag is a function of sliding speed and effective pressure. To compute effective pressure, these relationships must be inverted, either by explicitly rearranging the equations or by numerical root-finding. For all sliding laws, we ensure the effective pressure does not exceed the ice overburden pressure. The VGS provides a model of acoustic propagation in granular material. Substituting the estimated effective pressure (from the basal sliding law) into this model and using independent estimates for the grain diameter and porosity from sediment cores provides an estimate of acoustic impedance for each sliding law. The predicted acoustic impedance is then compared to acoustic impedance measurements collected at five sites on Pine Island Glacier (PIG) in Antarctica (Brisbourne et al., 2017). More specifically, the different models (VGS + sliding laws) are compared using Bayesian model selection. We assume the error of the data follows a Gaussian distribution and consider each model equally probable at the beginning. Since the parameter space differs between the models (number of individual parameters (dimensions) as well as number of tested parameter values), we apply Occam's razor, penalizing models with a larger parameter space. Details of all other data sets, including the basal drag and sliding speed inversion (Arthern et al., 2015) as well as the prior distributions, can be found in Hank et al. (2025). The contributing datasets used to constrain the model and parameter ranges are listed by Hank et al. (2025). The model was run between Nov 13, 2024 and Mar 11, 2025. The output is from the same date range. |
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| Temporal Coverage: | |
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| Start Date | 2024-11-13 |
| End Date | 2025-09-01 |
| Spatial Coverage: | |
| Latitude | |
| Southernmost | -90 |
| Northernmost | -60 |
| Longitude | |
| Westernmost | -135 |
| Easternmost | -80 |
| Altitude | |
| Min Altitude | 0 m |
| Max Altitude | 5000 m |
| Depth | |
| Min Depth | 0 m |
| Max Depth | -5000 m |
| Data Resolution: | |
| Latitude Resolution | N/A |
| Longitude Resolution | N/A |
| Horizontal Resolution Range | 1 km - < 10 km or approximately .01 degree - < .09 degree |
| Vertical Resolution | N/A |
| Vertical Resolution Range | N/A |
| Temporal Resolution | N/A |
| Temporal Resolution Range | N/A |
| Location: | |
| Location | Antarctica |
| Detailed Location | Amundsen Sea sector, Pine Island Glacier |
| Data Collection: | The misfit calculations were performed using Julia version 1.8.3. The Bayesian model selection and all other data processing was done using Python version 3.13.2. |
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| Distribution: | |
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| Distribution Media | Online Internet (HTTP) |
| Distribution Size | 83 GB |
| Distribution Format | netCDF |
| Fees | N/A |
| Data Storage: | The dataset is comprised of 35 netCDF files. |