Litcius/Paper detail

Regional sensitivity patterns of Arctic Ocean acidification revealed with machine learning

John P. Krasting, Maurizia De Palma, Maike Sonnewald, John P. Dunne, Jasmin G. John

2022Communications Earth & Environment13 citationsDOIOpen Access PDF

Abstract

Abstract Ocean acidification is a consequence of the absorption of anthropogenic carbon emissions and it profoundly impacts marine life. Arctic regions are particularly vulnerable to rapid pH changes due to low ocean buffering capacities and high stratification. Here, an unsupervised machine learning methodology is applied to simulations of surface Arctic acidification from two state-of-the-art coupled climate models. We identify four sub-regions whose boundaries are influenced by present-day and projected sea ice patterns. The regional boundaries are consistent between the models and across lower (SSP2-4.5) and higher (SSP5-8.5) carbon emissions scenarios. Stronger trends toward corrosive surface waters in the central Arctic Ocean are driven by early summer warming in regions of annual ice cover and late summer freshening in regions of perennial ice cover. Sea surface salinity and total alkalinity reductions dominate the Arctic pH changes, highlighting the importance of objective sub-regional identification and subsequent analysis of surface water mass properties.

Topics & Concepts

Ocean acidificationArcticEnvironmental scienceSea iceStratification (seeds)OceanographyArctic ice packArctic geoengineeringAlkalinityArctic sea ice declineSalinityClimatologyClimate changeGlobal warmingGeologyAntarctic sea iceChemistryBiologyBotanyGerminationDormancyOrganic chemistrySeed dormancyArctic and Antarctic ice dynamicsOcean Acidification Effects and ResponsesMarine and coastal ecosystems