Ocean circulation

2006: Freshwater flowing into the North Atlantic could shut down the ocean conveyor belt that shuttles warm water toward Western Europe.

2016: The ocean conveyor belt may already be slowing, but it’s not much of a conveyor belt at that.

Last year may have been Earth’s hottest on record (SN: 2/20/16, p. 13). But for one small corner of the globe, 2015 was one of the coldest. Surface temperatures in the subpolar North Atlantic have chilled in recent years and, oddly enough, some research suggests global warming is partly responsible.

An influx of freshwater from melting glaciers and increasing rainfall can slow — and possibly even shut down — the ocean currents that ferry warm water from the tropics to the North Atlantic. About 10 years ago, scientists warned of a possible abrupt shutdown of this “ocean conveyor belt.” After years of closely monitoring Earth’s flowing oceans, researchers say a sudden slowdown isn’t in the cards. Some researchers report that they may now be seeing a more gradual slowing of the ocean currents. Others, meanwhile, have discovered that Earth’s ocean conveyor belt may be less of a sea superhighway and more of a twisted network of side roads.

The consequences of a sea current slowdown won’t be anywhere near as catastrophic as the over-the-top weather disasters envisioned in the 2004 film The Day After Tomorrow, says Stephen Griffies, a physical oceanographer at NOAA’s Geophysical Fluid Dynamics Laboratory. “The doomsday scenario is overblown, but the possibility of a slowing down of the circulation is real and will have important impacts on Atlantic climates,” Griffies says.

EVERY WHICH WAY Tracking the motion of floating markers dropped into the northwest Atlantic (white-rimmed circles), researchers found that the idea of an ocean conveyor belt is overly simplistic. The markers quickly split up, ending up in many different destinations (solid circles).Amy S. Bower et al/Nature 2009

The Atlantic mixing that feeds the currents is powered by differences in the density of seawater. In the simple ocean conveyor-belt model, warm, less-dense surface water flows northward into the North Atlantic. Off Greenland, cold, denser water sinks into the deep ocean and flows southward. This heat exchange, known as the Atlantic overturning circulation, helps keep European cities warmer than their counterparts elsewhere in the world.

Ten years ago, scientists knew from past changes in Earth’s climate that temperature shifts can disrupt this density balance. Freshwater from the shrinking Greenland ice sheet and increased rainfall make the North Atlantic waters less dense and therefore less likely to sink. Investigations into Earth’s ancient climates show that the overturning circulation weakened around 12,800 years ago, probably causing cooling in Europe and sea level rise along North America’s East Coast, as piled-up water in the north sloshed southward.

Tracking sea surface temperatures, researchers reported last year that the Atlantic overturning circulation significantly slowed during the 20th century, particularly after 1970. Comparing the recent slowdown with past events, the researchers reported in March in Nature Climate Change that the rapid weakening of the circulation is unprecedented in the last 1,000 years.

That result isn’t the final word, though, says Duke University physical oceanographer Susan Lozier. Scientists have directly measured the speed of the ocean circulation only since the deployment of a network of ocean sensors in 2004. Earlier Atlantic circulation speed changes have to be gleaned from less reliable indirect sources such as sea surface temperature changes. “If you look at the most recent results, there’s a decline, yes,” she says. “But we can’t say that’s part of a long-term trend right now.” And effects on Europe’s climate could be masked by other factors.

Another challenge is that over the last 10 years, “the ocean conveyor-belt model broke,” Lozier said in February at the American Geophysical Union’s Ocean Sciences Meeting in New Orleans. From 2003 through 2005, she and colleagues tracked the movements of 76 floating markers dropped into the North Atlantic and pulled around by ocean waters. If the model was right, these markers should have traveled along the southward-flowing part of the conveyor belt. Instead, the markers moved every which way, the researchers reported in 2009 in Nature.

“We went from this simple ribbon of a conveyor belt to a complex flow field with multiple pathways,” Lozier says. Determining past and possible future effects of climate change on ocean currents will require more measurements and a better understanding of how the ocean truly flows, she says.

Even if the overturning circulation cuts out completely, the resulting cooling effect will probably be short-lived, Griffies says. “At some point, even if the circulation collapses, it would only be 10 or 20 years before the global warming signal would overwhelm that cooling” in Europe, he says. “This is not going to save us from a warmer planet.”