Short-term variations of Icelandic ice cap mass inferred from cGPS coordinate time series

As the global climate changes, understanding short-term variations in water storage is increasingly important. Continuously operating Global Positioning System (cGPS) stations in Iceland record annual periodic motion—the elastic response to winter accumulation and spring melt seasons—with peak-to-pe...

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Bibliographic Details
Published in:Geochemistry, Geophysics, Geosystems
Main Authors: Compton, Kathleen, Bennett, Richard A., Hreinsdóttir, Sigrún, van Dam, Tonie, Bordoni, Andrea, Barletta, Valentina Roberta, Spada, Giorgio
Format: Article in Journal/Newspaper
Language:English
Published: 2017
Subjects:
/dk/atira/pure/sustainabledevelopmentgoals/climate_action
SDG 13 - Climate Action
Ice cap
Iceland
Online Access:https://orbit.dtu.dk/en/publications/f4f86f07-038f-4f59-9982-797e96c1b194
https://doi.org/10.1002/2017GC006831
https://backend.orbit.dtu.dk/ws/files/134462088/Compton_et_al_2017_Geochemistry_Geophysics_Geosystems.pdf
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Summary:As the global climate changes, understanding short-term variations in water storage is increasingly important. Continuously operating Global Positioning System (cGPS) stations in Iceland record annual periodic motion—the elastic response to winter accumulation and spring melt seasons—with peak-to-peak vertical amplitudes over 20 mm for those sites in the Central Highlands. Here for the first time for Iceland, we demonstrate the utility of these cGPS-measured displacements for estimating seasonal and shorter-term ice cap mass changes. We calculate unit responses to each of the five largest ice caps in central Iceland at each of the 62 cGPS locations using an elastic half-space model and estimate ice mass variations from the cGPS time series using a simple least squares inversion scheme. We utilize all three components of motion, taking advantage of the seasonal motion recorded in the horizontal. We remove secular velocities and accelerations and explore the impact that seasonal motions due to atmospheric, hydrologic, and nontidal ocean loading have on our inversion results. Our results match available summer and winter mass balance measurements well, and we reproduce the seasonal stake-based observations of loading and melting within the 1 math formula confidence bounds of the inversion. We identify nonperiodic ice mass changes associated with interannual variability in precipitation and other processes such as increased melting due to reduced ice surface albedo or decreased melting due to ice cap insulation in response to tephra deposition following volcanic eruptions, processes that are not resolved with once or twice-yearly stake measurements.

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