Abstract
Abstract. The Atlantic Meridional Overturning Circulation (AMOC) is a key mechanism for large-scale northward heat transport and thus plays an important role for global climate. Relatively warm water is transported northward in the upper layers of the North Atlantic Ocean and, after cooling at subpolar latitudes, sinks down and is transported back south in the deeper limb of the AMOC. The utility of in situ ocean bottom pressure (OBP) observations to infer AMOC changes at single latitudes has been characterized in the recent literature using output from ocean models. We extend the analysis and examine the utility of space-based observations of time-variable gravity and the inversion for ocean bottom pressure to monitor AMOC changes and variability between 20 and 60° N. Consistent with previous results, we find a strong correlation between the AMOC signal and OBP variations, mainly along the western slope of the Atlantic Basin. We then use synthetic OBP data – smoothed and filtered to resemble the resolution of the GRACE (Gravity Recovery and Climate Experiment) gravity mission, but without errors – and reconstruct geostrophic AMOC transport. Due to the coarse resolution of GRACE-like OBP fields, we find that leakage of signal across the step slopes of the ocean basin is a significant challenge at certain latitudes. Transport signal rms is of a similar order of magnitude as error rms for the reconstructed time series. However, the interannual AMOC anomaly time series can be recovered from 20 years of monthly GRACE-like OBP fields with errors less than 1 sverdrup in many locations.
Highlights
Changes of the Atlantic Meridional Overturning Circulation (AMOC) and associated poleward ocean heat transport from the equatorial regions influence climate at higher latitudes significantly
Equation (3) is evaluated for different synthetic ocean bottom pressure (OBP) resolutions derived from ECCO2 in the North Atlantic: the original ECCO2 0.25◦ grid (T O), a GRACE spherical harmonics grid truncated at degree and order 60 (T SH60), GRACE mascon grids, without (T MSC) and with (T MSC + CRI) CRI filter, and position-optimized mascons (T MSC + POSOPT)
While the OBP signal on the western basin boundary contains most of the AMOC information, a basin mode has to be taken into account, either by differencing with the signal on the eastern boundary or by removing a depth-averaged OBP to remove variations not contributing to geostrophic transports (Bingham and Hughes, 2008, 2009a)
Summary
Changes of the Atlantic Meridional Overturning Circulation (AMOC) and associated poleward ocean heat transport from the equatorial regions influence climate at higher latitudes significantly. It has potentially significant impacts in particular for the Northern Hemisphere as well as northwestern Europe’s climate (Manabe and Stouffer, 1999; Srokosz et al, 2012; IPCC, 2014). The viability of using OBP along the eastern and western boundaries to calculate the basin-wide meridional geostrophic transports was first demonstrated with numerical ocean simulations (e.g., Bingham and Hughes, 2008, 2009a). Elipot et al (2013) used bottom pressure recorder (BPR) measurements along the western boundary to monitor the AMOC.
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