Atmospheric Contributions to Global Ocean Tides for Satellite Gravimetry
DOI: https://doi.org/10.1029/2022MS003193
Persistent URL: http://resolver.sub.uni-goettingen.de/purl?gldocs-11858/10886
Persistent URL: http://resolver.sub.uni-goettingen.de/purl?gldocs-11858/10886
Supplement: https://pypi.org/project/cdsapi/, https://mpimet.mpg.de/en/science/models/mpi-esm/mpiom, https://doi.org/10.5067/graod-1bg06
Balidakis, Kyriakos; Sulzbach, Roman; Shihora, Linus; Dahle, Christoph; Dill, Robert; Dobslaw, Henryk, 2022: Atmospheric Contributions to Global Ocean Tides for Satellite Gravimetry. In: Journal of Advances in Modeling Earth Systems, Band 14, 11, DOI: 10.1029/2022MS003193.
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To mitigate temporal aliasing effects in monthly mean global gravity fields from the GRACE and GRACE‐FO satellite tandem missions, both tidal and non‐tidal background models describing high‐frequency mass variability in atmosphere and oceans are needed. To quantify tides in the atmosphere, we exploit the higher spatial (31 km) and temporal (1 hr) resolution provided by the latest atmospheric ECMWF reanalysis, ERA5. The oceanic response to atmospheric tides is subsequently modeled with the general ocean circulation model MPIOM (in a recently revised TP10L40 configuration that includes the feedback of self‐attraction and loading to the momentum equations and has an improved bathymetry around Antarctica) as well as the shallow water model TiME (employing a much higher spatial resolution and more elaborate tidal dissipation than MPIOM). Both ocean models consider jointly the effects of atmospheric pressure variations and surface wind stress. We present the characteristics of 16 waves beating at frequencies in the 1–6 cpd band and find that TiME typically outperforms the corresponding results from MPIOM and also FES2014b as measured from comparisons with tide gauge data. Moreover, we note improvements in GRACE‐FO laser ranging interferometer range‐acceleration pre‐fit residuals when employing the ocean tide solutions from TiME, in particular, for the S1 spectral line with most notable improvements around Australia, India, and the northern part of South America. Plain Language Summary:
In addition to many rather slow processes such as the melting of glaciers, rapid mass redistribution related to the weather also measurably affect the Earth's gravity field. The ability of monitoring liquid freshwater changes within the Earth system from the satellite gravity missions GRACE (2002–2017) and GRACE‐FO (since 2018) relies on accurate background models of mass variability in atmosphere and oceans for both tidal and non‐tidal processes. Atmospheric tides are primarily excited in the middle atmosphere by solar energy absorption at periods of 24 hr and its overtones. We find additional tidal signatures in the atmosphere excited by periodic deformations of both crust and sea‐surface of the Earth. We thus introduce here a new data set for the atmospheric tides and their corresponding oceanic response that features both more waves and higher accuracy than other background models previously used for the processing of GRACE and GRACE‐FO satellite gravimetry data. Key Points:
Sixteen relevant tidal lines identified in hourly data from ERA5 atmospheric reanalysis.
Dedicated simulations with a high‐resolution global hydrodynamic model to simulate ocean tides with atmospheric influence.
New tidal models reduce pre‐fit residuals in GRACE‐FO Laser Ranging Interferometer data.
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