Scientists now have a better understanding of the risks ahead and a new early warning signal to watch for.
By Dr. R.M. (Renรฉ) van Westen
Postdoctoral Researcher in Climate Physics
Utrecht University
By Dr. H.A. (Henk) Dijkstra
Professor of Physics
Utrecht University
By Dr. M.A. (Michael) Kliphuis
Climate Model Specialist
Utrecht University
Introduction
Superstorms, abrupt climate shifts and New York City frozen in ice. Thatโs how the blockbuster Hollywood movie โThe Day After Tomorrowโ depicted an abrupt shutdown of the Atlantic Oceanโs circulation and the catastrophic consequences.
While Hollywoodโs vision was over the top, the 2004 movie raised a serious question: If global warming shuts down the Atlantic Meridional Overturning Circulation, which is crucial for carrying heat from the tropics to the northern latitudes, how abrupt and severe would the climate changes be?
Twenty years after the movieโs release, we know a lot more about the Atlantic Oceanโs circulation. Instruments deployed in the ocean starting in 2004ย show that the Atlantic Ocean circulationย hasย observably slowedย over the past two decades, possibly to itsย weakest state in almost a millennium. Studies also suggest that the circulation has reached aย dangerous tipping pointย inย the pastย that sent it into a precipitous, unstoppable decline, and that itย could hit that tipping point againย as the planet warms and glaciers and ice sheets melt.
In a new study using the latest generation of Earthโs climate models, we simulated the flow of fresh water until the ocean circulation reached that tipping point.
The results showed that the circulation couldย fully shut down within a centuryย of hitting the tipping point, and that itโs headed in that direction. If that happened, average temperatures would drop by several degrees in North America, parts of Asia and Europe, and people would see severe and cascading consequences around the world.
We also discovered a physics-based early warning signal that can alert the world when the Atlantic Ocean circulation is nearing its tipping point.
The Ocean’s Conveyor Belt
Ocean currents are driven by winds, tides and waterย density differences.
In the Atlantic Ocean circulation, the relatively warm and salty surface water near the equator flows toward Greenland. During its journey it crosses the Caribbean Sea, loops up into the Gulf of Mexico, and then flows along the U.S. East Coast before crossing the Atlantic.
This current, also known as the Gulf Stream, brings heat to Europe. As it flows northward and cools, the water mass becomes heavier. By the time it reaches Greenland, it starts to sink and flow southward. The sinking of water near Greenland pulls water from elsewhere in the Atlantic Ocean and the cycle repeats, like aย conveyor belt.
Too much fresh waterย from melting glaciers and the Greenland ice sheet can dilute the saltiness of the water, preventing it from sinking, and weaken thisย ocean conveyor belt. Aย weaker conveyor beltย transportsย less heat northwardย and also enables less heavy water to reach Greenland, whichย further weakensย the conveyor beltโs strength. Once it reaches theย tipping point, it shuts down quickly.
What Happens to the Climate at the Tipping Point?
The existence of a tipping point was first noticed in an overly simplified model of the Atlantic Ocean circulation in theย early 1960s. Todayโs moreย detailed climate modelsย indicate a continuedย slowing of the conveyor beltโs strengthย under climate change. However, an abrupt shutdown of the Atlantic Ocean circulationย appeared to be absentย in these climate models.
This is where our study comes in. We performed an experiment with a detailed climate model to find the tipping point for an abrupt shutdown by slowly increasing the input of fresh water.
We found that once it reaches the tipping point, the conveyor belt shuts down within 100 years. The heat transport toward the north is strongly reduced, leading to abrupt climate shifts.
The Result: Dangerous Cold in the North
Regions that are influenced by the Gulf Stream receiveย substantially less heatย when the circulation stops. This cools the North American and European continents by a few degrees.
The European climate is much more influenced by the Gulf Stream than other regions. In our experiment, that meant parts of the continent changed at more than 5 degrees Fahrenheit (3 degrees Celsius) per decade โ far faster than todayโs global warming of about 0.36 F (0.2 C) per decade. We found that parts of Norway would experience temperature drops of more than 36 F (20 C). On the other hand, regions in the Southern Hemisphere would warm by a few degrees.
These temperature changes develop over about 100 years. That might seem like a long time, but on typical climate time scales, it is abrupt.
The conveyor belt shutting down would also affect sea level and precipitation patterns, which canย push other ecosystems closer to their tipping points. For example, the Amazon rainforest is vulnerable toย declining precipitation. If its forest ecosystem turned to grassland, the transition wouldย release carbonย to the atmosphere and result in the loss of a valuable carbon sink, further accelerating climate change.
The Atlantic circulation hasย slowed significantly in the distant past. Duringย glacial periodsย when ice sheets that covered large parts of the planet were melting, the influx of fresh water slowed the Atlantic circulation, triggering huge climate fluctuations.
So, When Will We See This Tipping Point?
The big question โ when will the Atlantic circulation reach a tipping point โ remains unanswered. Observations donโt go back far enough to provide a clear result. While a recent study suggested that the conveyor belt is rapidlyย approaching its tipping point, possibly within a few years, these statistical analyses made several assumptions that give rise to uncertainty.
Instead, we were able to develop a physics-based and observable early warning signal involving the salinity transport at the southern boundary of the Atlantic Ocean. Once a threshold is reached, the tipping point is likely to follow in one to four decades.
The climate impacts from our study underline the severity of such an abrupt conveyor belt collapse. The temperature, sea level and precipitation changes will severely affect society, and theย climate shifts are unstoppableย on human time scales.
It might seem counterintuitive to worry about extreme cold as the planet warms, but if the main Atlantic Ocean circulation shuts down from too much meltwater pouring in, thatโs the risk ahead.
Originally published by The Conversation, 02.09.2024, under the terms of a Creative Commons Attribution/No derivatives license.
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