Abstract
Abstract. Deep and bottom water formation are crucial components of the global ocean circulation, yet they were poorly represented in the previous generation of climate models. We here quantify biases in Antarctic Bottom Water (AABW) and North Atlantic Deep Water (NADW) formation, properties, transport, and global extent in 35 climate models that participated in the latest Climate Model Intercomparison Project (CMIP6). Several CMIP6 models are correctly forming AABW via shelf processes, but 28 models in the Southern Ocean and all 35 models in the North Atlantic form deep and bottom water via open-ocean deep convection too deeply, too often, and/or over too large an area. Models that convect the least form the most accurate AABW but the least accurate NADW. The four CESM2 models with their overflow parameterisation are among the most accurate models. In the Atlantic, the colder the AABW, the stronger the abyssal overturning at 30∘ S, and the further north the AABW layer extends. The saltier the NADW, the stronger the Atlantic Meridional Overturning Circulation (AMOC), and the further south the NADW layer extends. In the Indian and Pacific oceans in contrast, the fresher models are the ones which extend the furthest regardless of the strength of their abyssal overturning, most likely because they are also the models with the weakest fronts in the Antarctic Circumpolar Current. There are clear improvements since CMIP5: several CMIP6 models correctly represent or parameterise Antarctic shelf processes, fewer models exhibit Southern Ocean deep convection, more models convect at the right location in the Labrador Sea, bottom density biases are reduced, and abyssal overturning is more realistic. However, more improvements are required, e.g. by generalising the use of overflow parameterisations or by coupling to interactive ice sheet models, before deep and bottom water formation, and hence heat and carbon storage, are represented accurately.
Highlights
Bottom water formation around Antarctica and deep water formation in the North Atlantic ventilate the global abyssal and deep ocean
North Atlantic Deep Water (NADW) production has long been linked to the strength of the Atlantic Meridional Overturning Circulation (AMOC, e.g. Broecker, 1995), observations from the recently deployed Overturning in the Subpolar North Atlantic Program (OSNAP) line (Lozier et al, 2019) suggest that this link is more complex than meaning more deep-water formation equals stronger AMOC
As we previously found an anticorrelation between the AMOC and the Atlantic SMOC across CMIP6 models, the Atlantic balance is complete: models with strong AMOC and weak SMOC have their Atlantic dominated by NADW (e.g. CESM2-WACCM), whereas those with a weak AMOC and strong SMOC are filled with Antarctic Bottom Water (AABW) (e.g. IPSL-CM6ALR)
Summary
Bottom water formation around Antarctica and deep water formation in the North Atlantic ventilate the global abyssal and deep ocean. NADW forms in the Labrador Sea and Nordic seas because of strong winds and haline convection, respectively (Killworth, 1983). It is the saltiest of the two water masses but is warmer and lighter than AABW and leaves the sea floor to continue circulating above AABW where the two meet (Johnson, 2008). Broecker, 1995), observations from the recently deployed Overturning in the Subpolar North Atlantic Program (OSNAP) line (Lozier et al, 2019) suggest that this link is more complex than meaning more deep-water formation equals stronger AMOC.
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