A new study challenges previous climate predictions by demonstrating that climate change has impacted the Southern Ocean\u2019s ability to absorb carbon dioxide. However, a delicate relationship remains in the balance.<\/p>\n
According to scientists from the Alfred Wegener Institute (AWI), a leading international center of polar and marine research, the Southern Ocean around Antarctica acts as a \u201ccarbon sink\u201d because it alone stores about 40% of anthropogenic CO\u2082 emissions\u2014that is, the CO\u2082 specifically released into the atmosphere by humans.<\/p>\n
Because of the crucial role the Southern Ocean plays in mitigating this catalyst for climate change, AWI researchers have been studying this marine environment. Observational data show that climate change has not yet appeared to diminish its ability to absorb CO\u2082. They sought to understand why, and recently published their results in Nature Climate Change.<\/p>\n
The chemical composition of the upper ocean, or the top layer most influenced by the atmosphere, has helped to trap carbon in the deep sea. But as climate change continues to alter the South Ocean, the critical question is whether it will be able to continue keeping carbon at bay, or if the carbon will finally be released into the atmosphere, threatening the world as we know it.<\/p>\n
Antarctica is the world\u2019s carbon \u201csink\u201d<\/p>\n
As long as natural CO\u2082 doesn\u2019t surface from the deep ocean, the Southern Ocean can continue to absorb anthropogenic CO\u2082, a press release explains. The upper layer of the sea, closest to the surface, keeps the denser, CO\u2082-rich waters contained due to its low saline content.<\/p>\n
\u201cThe water that upwells from the depths in the Southern Ocean is extremely old,\u201d having not surfaced for hundreds or thousands of years. Described by study authors as \u201csalty, nutrient-dense, and relatively warm,\u201d the Southern Ocean will continue to function as a \u201csink\u201d as long as the density stratification between these two layers remains intact.<\/p>\n
However, model studies predicted that strengthening westerly winds, provoked by climate change, would cause this CO\u2082-dense water to finally break to the surface. This expected event has not occurred, which has effectively curbed climate change. According to the study authors, the cold, low-salinity water of the upper ocean has continued to function as a natural barrier.<\/p>\n
The good news is that climate change hasn\u2019t changed the composition of the ocean around Antarctica yet. However, their study, which analyzed data from long-term observations and marine expeditions made between 1972 and 2021, found that \u201cthe two water masses have become more distinct from one another.\u201d<\/p>\n
Antarctica might not be a sink forever<\/p>\n
The Southern Ocean\u2019s surface water salinity has been reduced by the increased input of freshwater, caused by precipitation, but also by melting glaciers and sea ice. That reduction has actually reinforced the density stratification between the two layers, which has succeeded in keeping the CO\u2082-dense water beneath the surface.<\/p>\n
\u201cOur study shows that this fresher surface water has temporarily offset the weakening of the carbon<\/a> sink in the Southern Ocean, as model simulations predicted,\u201d the study authors said.<\/p>\n Nonetheless, they observed that ever since the 1990s, the upper boundary of deep water has shifted roughly 40 meters closer to the breaking point. As time goes on, that natural barrier might disappear if the two layers begin to mix.<\/p>\n Study authors weren\u2019t able to confirm whether or not the deep ocean has been releasing more CO\u2082 into the atmosphere in recent years. However, the results of the study suggest that the process might be underway.<\/p>\n What surprised leading climate<\/a> researchers, however, was the role the deep ocean plays in the overall picture: \u201cWe need to look beyond just the ocean\u2019s surface.\u201d<\/p>\n \u201cTo confirm whether more CO\u2082 has been released from the deep ocean in recent years, we need additional data, particularly from the winter months, when the water masses tend to mix,\u201d concluded Prof. Alexander Haumann, co-author of the study, in a press release<\/a>.<\/p>\n \u201cIn the coming years, the AWI is planning to carefully examine these exact processes as part of the international\u00a0Antarctica InSync\u00a0programme, and gain a better understanding of the effects of climate change<\/a> on the Southern Ocean and potential interactions.\u201c<\/p>\n