NCAR develops method to predict sea ice changes years in advance

Amid long-term retreat, winter sea ice could hold steady in the next several years

Dec 8, 2015 - by Staff

BOULDER – Climate scientists at the National Center for Atmospheric Research (NCAR) present evidence in a new study that they can predict whether the Arctic sea ice that forms in the winter will grow, shrink, or hold its own over the next several years.

The team of scientists has found that changes in the North Atlantic ocean circulation could allow overall winter sea ice extent to remain steady in the near future, with continued loss in some regions balanced by possible growth in others, including in the Barents Sea.

"We know that over the long term, winter sea ice will continue to retreat," said NCAR scientist Stephen Yeager, lead author of the new study, which appears in the journal Geophysical Research Letters. "But we are predicting that the rate will taper off for several years in the future before resuming. We are not implying some kind of recovery from the effects of human-caused global warming; it's really just a slow down in winter sea ice loss."

The research was funded largely by the National Science Foundation, NCAR's sponsor, with additional support from the National Oceanic and Atmospheric Administration and the U.S. Department of Energy.

side-by-side maps show observed and predicted winter sea ice loss

The researchers tested how well they were able to predict winter sea ice changes by "hindcasting" past decades and then comparing their retrospective predictions to observations of what really happened. This image shows how the model stacked up to real life for the period of 1997–2007. [Enlarge] (©UCAR. This image is freely available for media & nonprofit use.)

Yeager is among a growing number of scientists trying to predict how the climate may change over a few years to a few decades, instead of the more typical span of many decades or even centuries. This type of "decadal prediction" provides information over a timeframe that is useful for policy makers, regional stakeholders, and others.

Decadal prediction relies on the idea that some natural variations in the climate system, such as changes in the strength of ocean currents, unfold predictably over several years. At times, their impacts can overwhelm the general warming trend caused by greenhouse gases released into the atmosphere by humans.

Yeager's past work in this area has focused on decadal prediction of sea surface temperatures. A number of recent studies linking changes in the North Atlantic ocean circulation to sea ice extent led Yeager to think that it would also be possible to make decadal predictions for Arctic winter sea ice cover using the NCAR-based Community Earth System Model.

Linking ocean circulation and sea ice

The key is accurately representing the Atlantic Meridional Overturning Circulation (AMOC) in the model. AMOC sweeps warm surface waters from the tropics toward the North Atlantic, where they cool and then sink before making a return south in deep ocean currents. 

AMOC can vary in intensity. When it's strong, more warm water is carried farther toward the North Atlantic and Arctic oceans, accelerating sea ice loss. When weak, the warm water largely stays farther south, and its effects on sea ice are reversed. The variations in AMOC's vigor—from weak to strong or vice versa—occur over multiple years to decades, giving scientists some ability to predict in advance how it will affect winter sea ice, in particular. 

An image of predicted sea ice change from 2007 to 2017

For the decade of 2007‑2017, the research team predicts that there may be some growth of winter sea ice in the Arctic Ocean, particularly on the Atlantic side, where scientists have the most confidence in the model's ability. The image also shows possible sea ice loss in the North Pacific. [Enlarge] For an image of predicted winter sea ice change from 2013‑2023, click here. (©UCAR. This image is freely available for media & nonprofit use.)

AMOC now appears to be weakening. Yeager and his co-authors, NCAR scientists Alicia Karspeck and Gokhan Danabasoglu, found in their new study that this change in the ocean is likely to be enough to temporarily mask the impacts of human-caused climate change and stall the associated downward trend in winter sea ice extent in the Arctic, especially on the Atlantic side, where AMOC has the most influence.

The limits of a short satellite record

The amount of sea ice covering the Arctic typically grows to its maximum in late February after the long, dark winter. The sea ice minimum typically occurs at the end of the summer season, in late September. The new study addresses only winter sea ice, which is less vulnerable than summer ice to variations in weather activity that cannot be predicted years in advance, such as storms capable of breaking up the ice crust.

Despite their success incorporating AMOC conditions into winter sea ice "hindcasts," the scientists are cautious about their predictions of future conditions. Because satellite images of sea ice extend only back to 1979, the scientists had a relatively short data record for verifying decadal-scale predictions against actual conditions. Additionally, AMOC itself has been measured directly only since 2004, though observations of other variables that are thought to change in tandem with AMOC—such as sea surface height and ocean density in the Labrador Sea, as well as sea surface temperature in the far North Atlantic—go back much farther.

"The sea ice record is so short that it's difficult to use statistics alone to build confidence in our predictions," Yeager said. "Much of our confidence stems from the fact that our model does well at predicting slow changes in ocean heat transport and sea surface temperature in the subpolar North Atlantic, and these appear to impact the rate of sea ice loss. So, we think that we understand the mechanisms underpinning our sea ice prediction skill."

About the article

Title: Predicted slow-down in the rate of Atlantic sea ice loss
Authors: Stephen G. Yeager, Alicia Karspeck, and Gokhan Danabasoglu
Publication: Geophysical Research Letters


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Laura Snider, Senior Science Writer and Public Information Officer

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