Downscaling GRACE-derived ocean bottom pressure anomalies using self-supervised data fusion

TL;DR

This paper introduces a self-supervised deep learning method to enhance the spatial resolution of GRACE-derived ocean bottom pressure anomalies, improving detail and coastal accuracy without high-resolution ground truth.

Contribution

It presents a novel data fusion approach that combines satellite gravity data with ocean reanalysis models to produce high-resolution ocean bottom pressure maps.

Findings

Downscaled products match GRACE solutions at large scales

Improved spatial detail and coastal signal accuracy

Better agreement with tide gauge measurements

Abstract

The gravimetry measurements from the Gravity Recovery and Climate Experiment (GRACE) and its follow-on (GRACE-FO) satellite mission provide an essential way to monitor changes in ocean bottom pressure ($p_b$), which is a critical variable in understanding ocean circulation. However, the coarse spatial resolution of the GRACE(-FO) fields blurs important spatial details, such as $p_b$ gradients. In this study, we employ a self-supervised deep learning algorithm to downscale global monthly $p_b$ anomalies derived from GRACE(-FO) observations to an equal-angle $0.25^\circ$ grid in the absence of high-resolution ground truth. The optimization process is realized by constraining the outputs to follow the large-scale mass conservation contained in the gravity field estimates while learning the spatial details from two ocean reanalysis products. The downscaled product agrees with GRACE(-FO) solutions over large ocean basins at the millimeter level in terms of equivalent water height and shows signs of outperforming them when evaluating short spatial scale variability. In particular, the downscaled $p_b$ product has more realistic signal content near the coast and exhibits better agreement with tide gauge measurements at around 80% of 465 globally distributed stations. Our method presents a novel way of combining the advantages of satellite measurements and ocean models at the product level, with potential downstream applications for studies of the large-scale ocean circulation, coastal sea level variability, and changes in global geodetic parameters.