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Stirring up the Seven Seas
November 18, 2022
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by
Sarah Blount & Sarah Hubbart

Does the phrase “the seven seas” sound familiar to you?

Early Greeks used the term to encompass the Aegean, Adriatic, Mediterranean, Black, Red, and Caspian Seas (with the Persian Gulf); later it was used in Medieval European literature to describe the North, Baltic, Mediterranean, Black, Red, and Arabian Seas, as well as the Atlantic Ocean. 

In modern times, the seven seas refer to regions of Earth’s five oceans—the Arctic, North Atlantic, South Atlantic, North Pacific, South Pacific, Indian, and Southern Oceans. 

Throughout history, these bodies of water were viewed as distinct regions, adapted over time to embrace the expanding edges of explorers' maps and nautical charts.

Today, however, we know that these regions of the watery world are not as disparate as early explorers may have once thought. Each of these bodies of water—from the frigid reaches of the Southern Ocean around Antarctica, to the balmy stretches of the Caribbean Sea, to the icy waters surrounding the Aleutian Islands—are connected through a deep-ocean current called the global ocean conveyor belt

This global circulation pattern helps cycle nutrients and energy across the planet, supporting the world’s food chain and creating a dynamic marine environment. The current influences how the ocean stores solar radiation, distributes heat and moisture around the globe, and drives weather systems.

Travel on the Global Ocean Conveyor Belt

The global current, also referred to as the ​​Meridional Overturning Circulation (MOC), is powered by changes in ocean chemistry in different parts of the world. Local differences in seawater temperature and levels of salinity give different parcels of water varying densities, causing them to sink or rise in the water column. 

Very cold, salty water—found in the Arctic Ocean where the formation of sea ice excludes salt and increases the salinity of the surrounding waters—is very dense, and thus sinks thousands of meters down to the ocean floor. 

Once at the bottom of the water column, this cold, dense water spreads out to make room for incoming water that is continuing to chill and sink from the surface. This sinking motion pulls in more water from the surrounding surface, creating a current. Together, this process is called thermohaline circulation.

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Illustration of the Great Ocean Conveyor Belt

The Great Ocean Conveyor Belt: The blue color represents a deeper, colder, saltier water current with the red color indicating a shallower and warmer current.

As it spreads at depth, the dense, cold water has nowhere to go but south. It moves across the floor of the Atlantic Ocean, past the equator, and on towards the Antarctic continent, where it is pushed around the southern landmass and fed more cold, salty water sinking from the surface. From here, the waters split—some of it is pushed back north towards the Indian subcontinent, and the rest moves towards the North Pacific. 

On this journey north, the waters are warmed by the sun, becoming less dense and rising up in the water column as a result of surface winds, equatorial heat influx, and salinity reduction. Once the water reaches its new, higher position in the water column, it once again spreads to make room for more rising water parcels, creating the second half of the current of the global ocean conveyor belt. The Atlantic Ocean’s circulation of heat from the equator up to the Arctic is what helps keep weather conditions mild in Europe and the eastern US.

How Will Climate Change Impact Ocean Currents?

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Icebergs floating on the water

This global current is vital in providing for the planet’s ecosystems—but it is at risk of being impacted by climate change. While the ocean’s conveyor belt is strong, it is also easily disrupted. An influx of warm freshwater from melting glaciers could disrupt the flow of sinking, colder water, and thereby slow or even stop the current in some regions.

This is already occurring in places like Greenland, where ice is melting at an accelerated pace. Research published in the journal Nature found that the Atlantic Ocean’s circulation has slowed by about 15 percent since the middle of the last century. Another study warns that the current is in the weakest state experienced in decades, if not centuries. 

There are still many unanswered questions about how and why the slowdown is happening. Recent research points to climate change as at least playing a small part. Scientists also believe that the current is still operating in what is historically “normal” behavior and within the bounds of natural variability. However, as the world continues to warm, we could enter uncharted territory. 

The Global Current and You

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Drying lakebed in the sun

Changes in the global current could lead to major climate shifts. For example, if the MOC in the Atlantic Ocean continues to slow, all countries bordering it will likely experience temperature and weather changes. One study suggests that Europe could see much colder winters and hotter summers. 

Weather changes could mean shifts in where food is grown and where people are able to live safely. Currents have a big impact on our economy because they affect global shipping, commercial fishing, recreational boating, and other sectors. Slowing currents could lead to rising sea levels along the eastern seaboard of the US, a disruptive and dangerous phenomenon that some American cities are already preparing for.

Additionally, the ocean plays a vital role in Earth’s carbon cycle. The deep ocean acts as our planet’s largest carbon dioxide reservoir. In fact, the total amount of carbon in the ocean is about 50 times greater than the amount in the atmosphere. 

A slower current will decrease the churning of carbon dioxide in the ocean, keeping more of it in surface waters. This increasing acidification is harmful to marine life, as well as the people and communities that depend upon fish and the ocean-based economy

Learn More About Ocean Currents and Climate Change

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Waves washing up on the shoreline

The next time you are at the beach, take a moment to consider how far that water has traveled and reflect on the many ways that the ocean and its currents impact your life. The “seven seas” are actually interconnected and complex ecosystems that support everyone on Earth. It’s important to understand what a warming planet could mean for the MOC—and how we can each take action to prevent climate change. 

Students and adults alike can learn more about the important role of ocean currents in our lives and ways to address the threat of climate change from the below resources.

  • Climate Kids (NASA): Upper elementary-age kids can learn how climate change affects the ocean through games, activities, and information from NASA.
  • The Great Ocean Conveyor (Earth Science Week): An interactive activity from the National Oceanic and Atmospheric Administration that helps students in grades 6-10 understand the movement of the currents.
  • The Ocean And Climate (PBS): Grades 9-12 can explore data, maps, and visualizations to better understand the various factors that influence global ocean circulation. 
  • Extreme Weather 101 (NEEF): Learn the basics about extreme weather and climate change—and how your family can stay prepared—from NEEF’s online course geared toward adults. 
  • Climate Change At Home (NPS): The National Park Service shares positive actions each of us can take to reduce our greenhouse gas emissions for the benefit of people, parks, and the planet. 
  • You Can Change the World: This book for ages 8-12 empowers kids with the powerful message that anyone can make a difference in the world by practicing everyday.
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