Geodetic observations for constraining mantle processes in Antarctica

Journal Article (2023)
Authors

Mirko Scheinert (Technische Universität Dresden)

Olga Didova (Universität Bonn, TU Delft - Physical and Space Geodesy)

E. J.O. Schrama (Astrodynamics & Space Missions)

Wouter van der Wal (Astrodynamics & Space Missions, TU Delft - Physical and Space Geodesy)

Martin Horwath (Technische Universität Dresden)

Affiliation
Astrodynamics & Space Missions
Copyright
© 2023 Mirko Scheinert, Olga Engels, Ernst Schrama, W. van der Wal, Martin Horwath
To reference this document use:
https://doi.org/10.1144/M56-2021-22
More Info
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Publication Year
2023
Language
English
Copyright
© 2023 Mirko Scheinert, Olga Engels, Ernst Schrama, W. van der Wal, Martin Horwath
Affiliation
Astrodynamics & Space Missions
Issue number
1
Volume number
56
Pages (from-to)
295-313
DOI:
https://doi.org/10.1144/M56-2021-22
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Abstract

Geodynamic processes in Antarctica such as glacial isostatic adjustment (GIA) and post-seismic deformation are measured by geo-detic observations such as global navigation satellite systems (GNSS) and satellite gravimetry. GNSS measurements have comprised both continuous measurements and episodic measurements since the mid-1990s. The estimated velocities typically reach an accuracy of 1 mm a−1 for horizontal velocities and 2 mm a−1 for vertical velocities. However, the elastic deformation due to present-day ice-load change needs to be considered accordingly. Space gravimetry derives mass changes from small variations in the inter-satellite distance of a pair of satellites, starting with the GRACE (Gravity Recovery and Climate Experiment) satellite mission in 2002 and continuing with the GRACE-FO (GRACE Follow-On) mission launched in 2018. The spatial resolution of the measurements is low (about 300 km) but the measurement error is homogeneous across Ant-arctica. The estimated trends contain signals from ice-mass change, and local and global GIA signals. To combine the strengths of the individual datasets, statistical combinations of GNSS, GRACE and satellite altimetry data have been developed. These combinations rely on realistic error estimates and assumptions of snow density. Nevertheless, they capture signals that are missing from geodynamic forward models such as the large uplift in the Amundsen Sea sector caused by a low-viscous response to century-scale ice-mass changes.