Ecologists and oceanographers are attempting to predict future climate based on that of the past. Click on image for full size (105 Kb) Image Courtesy of Chuck Greene, Cornell

Ecologists and oceanographers are attempting to predict the future impacts of climate change by reconstructing the past behavior of Arctic climate and ocean circulation.

In a November special issue of the journal Ecology, a group of scientists report that if current patterns of change in the Arctic and North Atlantic Oceans continue, alterations of ocean circulation could occur on a global scale, with potentially dramatic implications for the world's climate and biosphere.

"This research presents a compelling example of how climate change has altered marine ecosystems," said David Garrison, director of the National Science Foundation (NSF)'s Biological Oceanography Program, which funded the research. "It illustrates the value of basic research in understanding the underlying mechanisms and consequences of rapid climate change."

Charles Greene of Cornell University and colleagues reconstructed the patterns of climate change in the Arctic from the Paleocene epoch to the present.

Over these 65 million years, the Earth has undergone several major warming and cooling episodes, which were largely mitigated by the expansion and contraction of sea ice in the Arctic.

"When the Arctic cools and ice sheets and sea ice expand, the increased ice cover increases albedo, or reflectance of the sun's rays by the ice," says Greene, the lead author on the paper. "When more of the sun is reflected rather than absorbed, this leads to global cooling."

Likewise, when ice sheets and sea ice contract and expose the darker-colored land or ocean underneath, heat is absorbed, accelerating climate warming.

Currently, the Earth is in the midst of an interglacial period, characterized by retracted ice sheets and warmer temperatures.

In the past three decades, changes in Arctic climate and ice cover have led to several reorganizations of northern ocean circulation patterns.

Since 1989, a species of plankton native to the Pacific Ocean has been colonizing the North Atlantic Ocean, a feat that hasn't occurred in more than 800 thousand years. These plankton were carried across the Arctic Ocean by Pacific waters that made their way to the North Atlantic.

"When Arctic climate changes, waters in the Arctic can go from storing large quantities of freshwater to exporting that freshwater to the North Atlantic in large pulses, referred to as great salinity anomalies," Greene explains. "These GSAs flow southward, disrupting the ocean's circulation patterns and altering the temperature stratification observed in marine ecosystems."

In the continental shelf waters of the Northwest Atlantic, the arrival of a GSA during the early 1990s led to a major ecosystem reorganization, or regime shift. Some ocean ecosystems in the Northwest Atlantic saw major drops in salinity, increased stratification, an explosion of some marine invertebrate populations and a collapse of cod stocks.

"The changes in shelf ecosystems between the 1980s and 1990s were remarkable," says Greene. "Now we have a much better idea about the role climate had in this regime shift."

The changes observed in recent decades are only the tip of the iceberg. Previous interglacial periods have ended when the global ocean's deep circulation slowed in response to reductions in the formation of North Atlantic Deep Water, or NADW, a large, deep mass of highly saline water in the North Atlantic.

At these tipping points in the Earth's history, NADW formation was disrupted by pulses of freshwater entering the North Atlantic. The slowing of the global ocean's deep circulation results in less heat being transported to higher latitudes, accelerating ice formation and advancing the Earth into glacial conditions.

Recent modeling studies show that NADW formation will likely be resilient to freshwater pulses from the Arctic during the 21st century, according to the authors.

Continued exposure to such freshwater forcing, however, could disrupt global ocean circulation during the next century and lead to very abrupt changes in climate, similar to those that occurred at the onset of the last ice age.

"If the Earth's deep ocean circulation were to be shut down, many of the atmospheric, glacial and oceanic processes that have been stable in recent times would change, and the change would likely be abrupt," says Greene.

"While the ecosystem consequences of gradual changes in the ocean are somewhat predictable, all bets are off after such abrupt changes occur."

Text above is courtesy of the National Science Foundation

Ecologists and oceanographers are attempting to predict future climate based on that of the past. Click on image for full size (105 Kb) Image Courtesy of Chuck Greene, Cornell

Scientists are using what they know about ocean circulation and the past climates in the Arctic region to predict the future impacts of climate change. They think if the changes that are currently happening in the Arctic and North Atlantic Oceans continue, changes in ocean circulation will occur that could affect other oceans on Earth, and this could cause major changes in the world's climate.

The scientists looked at the patterns of climate change in the Arctic over the last 65 million years. In that time, the Earth has undergone different periods of warming and cooling. When the Earth warms, sea ice in the Arctic gets smaller; when the Earth cools, Arctic sea ice expands.

Charles Greene, the lead author on the study, explains, "When the Arctic cools and ice sheets and sea ice expand, the increased ice cover increases albedo, or reflectance of the sun's rays by the ice. When more of the sun is reflected rather than absorbed, this leads to global cooling."

Likewise, when ice sheets and sea ice get smaller, the darker-colored land or ocean underneath is exposed, heat is absorbed, and climate warming increases. Currently, the Earth is in a period where the ice sheets are smaller and the temperatures are warmer. These changes in Arctic climate and ice cover have led to several major changes in northern ocean circulation patterns over the last thirty years.

Dr. Greene explains that when Arctic climate changes, waters in the Arctic Ocean can go from storing large quantities of freshwater to sending that freshwater to the North Atlantic. Once these waters flow southward, they disrupt the ocean's circulation patterns and change the temperature of the water. This happened in the early 1990s and led to a major shift in the ecosystems of the Northern Atlantic Ocean. In some parts of the ocean there were major drops in salinity, the water temperatures changed, and there was an increase in the amount of plankton. Some of these changes hadn't occurred in over 800,000 years, so scientists see this as an example of a large impact of climate change.

Ecologists and oceanographers are attempting to predict future climate based on that of the past. Click on image for full size (105 Kb) Image Courtesy of Chuck Greene, Cornell

Scientists have been looking at the climates of the past in the Arctic region, and they think this information can help predict what might happen with the Earth's climate in the future.

The scientists looked at the patterns of climate change in the Arctic over the last 65 million years. In that time, the Earth has undergone different periods of warming and cooling. When the Earth warms, sea ice in the Arctic gets smaller; when the Earth cools, Arctic sea ice expands.

After studying the ocean currents of the Arctic Ocean and the Northern Atlantic Ocean, the scientists have learned that ocean circulation changes when the Earth's climate is warmer or cooler. Dr Charles Greene, the lead scientist of this study, explains that when the climate changes and gets warmer in Arctic, waters in the Arctic Ocean send freshwater that has melted south to the North Atlantic Ocean. Once these waters flow to the south, they change the ocean circulation patterns and change the temperature of the water. These changes impact what life can live in different parts of the worlds oceans and affects the Earth's climate, possibly making the climate cool due to the changes in ocean circulation.