Ocean-Ice Interactions in Inglefield Gulf: Early Results from NASA’s Oceans Melting Greenland Mission

Tracy and Heilprin, marine-terminating glaciers that drain into the eastern end of Inglefield Gulf in northwest Greenland, exhibit remarkably different behaviors despite being adjacent systems. Losing mass since 1892, Tracy Glacier has dramatically accelerated, thinned, and retreated. Heilprin has r...

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Bibliographic Details
Published in:Oceanography
Main Authors: Josh Willis, Dustin Carroll, Ian Fenty, Gurjot Kohli, Ala Khazendar, Matthew Rutherford, Nicole Trenholm, Mathieu Morlighem
Format: Article in Journal/Newspaper
Language:English
Published: The Oceanography Society 2018
Subjects:
OMG
Oceans Melting Greenland
Greenland
Tracy glacier
Heilprin
Oceanography
GC1-1581
Tracy Glacier
glacier
Online Access:https://doi.org/10.5670/oceanog.2018.211
https://doaj.org/article/1bc614bdabda47f9bff70831b20420e7
Description
Summary:Tracy and Heilprin, marine-terminating glaciers that drain into the eastern end of Inglefield Gulf in northwest Greenland, exhibit remarkably different behaviors despite being adjacent systems. Losing mass since 1892, Tracy Glacier has dramatically accelerated, thinned, and retreated. Heilprin has retreated only slightly during the last century and has remained almost stationary in the most recent decade. Previous studies suggest that Tracy’s base is deeper than Heilprin’s at the calving front (over 600 m, as opposed to the 350 m depth at Heilprin), which exposes it to warmer subsurface waters, resulting in more rapid retreat. We investigate the local oceanographic conditions in Inglefield Gulf and their interactions with Tracy and Heilprin using data collected in 2016 and 2017 as part of NASA’s Oceans Melting Greenland mission. Based on improved estimates of the fjord geometry and 20 temperature and salinity profiles near the fronts of these two glaciers, we find clear evidence that fjord waters are modified by ocean-ice interactions with Tracy Glacier. We find that Tracy thinned by 9.9 m near its terminus between 2016 and 2017, while Heilprin thinned by only 1.8 m. Using a simple subglacial plume model, we find that Tracy’s deeper depth at the front results in a more vigorous entrainment of warm subsurface waters, leading to more rapid melting. Model results support the hypothesis that Tracy’s deeper front results in faster glacier retreat, despite the presence of a shallow sill (~300 m) that may prevent the warmest waters from reaching Tracy.

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