Scientists finally know what caused the Atlantic Warming Hole
For years, scientists were puzzled by a strange part of the ocean just south of Greenland that didn't behave like the rest of the planet. While ocean temperatures across the globe have climbed steadily, this region, nicknamed the Atlantic Warming Hole, has cooled by nearly half a degree Fahrenheit over the last century. Now, researchers say they may have solved the mystery.
Despite its name, this location isn't warm at all. It's actually a cold zone in the North Atlantic where temperatures have dropped even as the rest of the ocean warms. That kind of anomaly has serious implications, especially for climate forecasting. The main question, though, is what could possibly cause this cooling in a rapidly warming world?
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According to new research published in Communications Earth and Environment, the answer lies in the slowing of a major system of ocean currents called the Atlantic Meridional Overturning Circulation, or AMOC. This network moves warm water from the tropics northward, where it cools, sinks, and flows back south. It's one of the key drivers of the planet's climate.
When the AMOC slows down, it disrupts this flow of heat. Less warm water reaches the North Atlantic, and the surface cools as a result. The researchers found that only climate models including this slowdown could recreate the observed temperature patterns in the Atlantic Warming Hole.
To reach this conclusion, scientists analyzed over a century of temperature data, which serve as indirect indicators of the ocean's current strength. They also used dozens of computer models to simulate how different changes would affect ocean temperatures. Only those with a weakened AMOC lined up with the observed cooling trend.
Understanding the Atlantic Warming Hole is important because this cold patch influences rainfall and wind patterns across Europe and can disrupt marine ecosystems. And as the AMOC continues to slow, some scientists warn of broader disruptions to weather and climate systems.
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