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Stefan Rahmstorf, Professor of Physics os the Ocean at the University of Potsdam since 2000, presents a colloquium on the risks associated with the destabilization of the Atlantic Meridional Overturning Circulation (AMOC) and its potential consequences for the global climate.

Des mesures de circulation et des recommandations sanitaires sont instaurées en raison d’épisodes de pollution aux particules fines et à l’ozone dans plusieurs régions.

Une étude néerlandaise estime que, en cas d’arrêt de l’AMOC, la circulation océanique qui régule le climat mondial et européen, le nord-ouest du Vieux Continent connaîtrait des températures hivernales chutant par endroits de 15 °C.

Recent simulations using the Community Earth System Model (CESM) indicate that a tipping event of the Atlantic Meridional Overturning Circulation (AMOC) would cause Europe to cool by several degrees. This AMOC tipping event was found under constant pre-industrial greenhouse gas forcing, while global warming likely limits this AMOC-induced cooling response. Here, we quantify the European temperature responses under different AMOC regimes and climate change scenarios. A strongly reduced AMOC state and intermediate global warming (C, Representative Concentration Pathway 4.5) has a profound cooling effect on Northwestern Europe with more intense cold extremes. The largest temperature responses are found during the winter months and these responses are strongly influenced by the North Atlantic sea-ice extent. Enhanced North Atlantic storm track activity under an AMOC collapse results in substantially larger day-to-day temperature fluctuations. We conclude that the (far) future European temperatures are dependent o

Située à la croisée des mondes slave, turc et balkanique, la mer Noire était, avant l’invasion russe de l’Ukraine le 24 février 2022, une artère importante du commerce mondial par laquelle circulaient 40 % des exportations de céréales. Aujourd’hui, le trafic s’est tari par rapport à 2022, mais, malgré l’insécurité, les mines, les sanctions, les réticences des assureurs face aux risques, les cargaisons de blé ukrainiennes comme russes continuent d’être exportées via ses couloirs maritimes.

Tipping elements within the Earth system are increasingly well understood. Scientists have identified more than 25 parts of the Earth’s climate system that are likely to have “tipping points” – thresholds where a small additional change in global warming will cause them to irreversibly shift into a new state. The “tipping” of these systems – which include the Atlantic Meridional Overturning Circulation (AMOC), the Amazon rainforest and the Greenland ice sheet – would have profound consequences for both the biosphere and people. More recent research suggests that triggering one tipping element could cause subsequent changes in other tipping elements, potentially leading to a “tipping cascade”. For example, a collapsed AMOC could lead to dieback of the Amazon rainforest and hasten the melt of the Greenland ice sheet.

The Antarctic Circumpolar Current (ACC) is the world's strongest ocean current and plays a disproportionate role in the climate system due to its role as a conduit for major ocean basins. This current system is linked to the ocean's vertical overturning circulation, and is thus pivotal to the uptake of heat and CO2 in the ocean. The strength of the ACC has varied substantially across warm and cold climates in Earth's past, but the exact dynamical drivers of this change remain elusive. This is in part because ocean models have historically been unable to adequately resolve the small-scale processes that control current strength. Here, we assess a global ocean model simulation which resolves such processes to diagnose the impact of changing thermal, haline and wind conditions on the strength of the ACC. Our results show that, by 2050, the strength of the ACC declines by ∼20% for a high-emissions scenario. This decline is driven by meltwater from ice shelves around Antarctica, which is exported to lower latit

The Atlantic Meridional Overturning Circulation (AMOC), vital for northwards heat transport in the Atlantic Ocean, is projected to weaken owing to global warming1, with significant global climate impacts2. However, the extent of AMOC weakening is uncertain with wide variation a …

Un nouvel article du grand climatologue James Hansen affirme que le réchauffement a accéléré il y a quelques années. La réduction des aérosols liés au fuel des navires en serait la cause. La fonte du Groenland dépasse les prévisions et mènera à un arrêt de la circulation océanique dans 20 -30 ans, ce qui provoquera plus tard une importante montée du niveau de la mer. Il suggère des prévisions climatiques complémentaires à celles du GIEC, qui s’appuieraient plus sur les observations de la réalité.

L’AMOC, qui contribue à maintenir un climat doux en Europe, des pluies dans les tropiques et qui stocke du CO₂, devrait ralentir, et pourrait même s’arrêter, en raison du dérèglement climatique.

Pourquoi l’effondrement pourrait être beaucoup plus proche que prévu : que se passe-t-il lorsque le cœur de l’océan Atlantique s’arrête de battre ?

On why collapse could be much closer than predicted: what happens when the Atlantic Ocean’s heart stops beating?

Le système de circulation océanique mondial, véritable moteur climatique de notre planète, montre des signes alarmants de ralentissement. Cette gigantesque « courroie de transmission » marine, qui régule la distribution de chaleur à l’échelle planétaire, est sur le point de s’effondrer. Les scientifiques tirent la sonnette d’alarme : les conséquences pourraient être dévastatrices pour le climat et les écosystèmes terrestres.

The Atlantic Meridional Overturning Circulation is the main driver of northward heat transport in the Atlantic Ocean today, setting global climate patterns. Whether global warming has affected the strength of this overturning circulation over the past century is still debated: observational studies suggest that there has been persistent weakening since the mid-twentieth century, whereas climate models systematically simulate a stable circulation. Here, using Earth system and eddy-permitting coupled ocean–sea-ice models, we show that a freshening of the subarctic Atlantic Ocean and weakening of the overturning circulation increase the temperature and salinity of the South Atlantic on a decadal timescale through the propagation of Kelvin and Rossby waves. We also show that accounting for upper-end meltwater input in historical simulations significantly improves the data–model agreement on past changes in the Atlantic Meridional Overturning Circulation, yielding a slowdown of 0.46 sverdrups per decade since 1950

The idea that the AMOC is headed to collapse is very controversial, but it is clearly weakening. If the circulation did collapse, the consequences on both sides of the Atlantic Ocean would be immense—including large changes in temperature and a spike in weather-related disasters.