Article

Ice island thinning: rates and model calibration with in situ observations from Baffin Bay, Nunavut

Details

Citation

Crawford AJ, Mueller D, Crocker G, Mingo L, Desjardins L, Dumont D & Babin M (2020) Ice island thinning: rates and model calibration with in situ observations from Baffin Bay, Nunavut. The Cryosphere, 14 (3), pp. 1067-1081. https://doi.org/10.5194/tc-14-1067-2020

Abstract
A 130 km2 tabular iceberg calved from Petermann Glacier in northwestern Greenland on 5 August 2012. Subsequent fracturing generated many individual large “ice islands”, including Petermann ice island (PII)-A-1-f, which drifted between Nares Strait and the North Atlantic. Thinning caused by basal and surface ablation increases the likelihood that these ice islands will fracture and disperse further, thereby increasing the risk to marine transport and infrastructure as well as affecting the distribution of freshwater from the polar ice sheets. We use a unique stationary and mobile ice-penetrating radar dataset collected over four campaigns to PII-A-1-f to quantify and contextualize ice island surface and basal ablation rates and calibrate a forced convection basal ablation model. The ice island thinned by 4.7 m over 11 months. The majority of thinning (73 %) resulted from basal ablation, but the volume loss associated with basal ablation was ∼12 times less than that caused by areal reduction (e.g. wave erosion, calving, and fracture). However, localized thinning may have influenced a large fracture event that occurred along a section of ice that was ∼40 m thinner than the remainder of the ice island. The calibration of the basal ablation model, the first known to be conducted with field data, supports assigning the theoretically derived value of 1.2×10−5 m2∕5 s ∘C−1 to the model's bulk heat transfer coefficient with the use of an empirically estimated ice–ocean interface temperature. Overall, this work highlights the value of systematically collecting ice island field data for analyzing deterioration processes, assessing their connections to ice island morphology, and adequately developing models for operational and research purposes.

Keywords
Earth-Surface Processes; Water Science and Technology

Journal
The Cryosphere: Volume 14, Issue 3

StatusPublished
FundersEnvironment and Climate Change Canada
Publication date24/03/2020
Publication date online24/03/2020
Date accepted by journal07/02/2020
URLhttp://hdl.handle.net/1893/36451
PublisherCopernicus GmbH
ISSN1994-0424

People (1)

Dr Anna Crawford

Dr Anna Crawford

Lecturer in Physical Geography, Biological and Environmental Sciences

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