North Atlantic Warming Tied to Natural Variability

admin — Thu, 01 Oct 2009 18:27:56 +0000

But global warming may be at play elsewhere in the world’s oceans, scientists surmise

Friday, January 4, 2008

Durham, NC — A Duke University-led analysis of available records shows that while the North Atlantic Oceanâ€™s surface waters warmed in the 50 years between 1950 and 2000, the change was not uniform. In fact, the subpolar regions cooled at the same time that subtropical and tropical waters warmed.

This striking pattern can be explained largely by the influence of a natural and cyclical wind circulation pattern called the North Atlantic Oscillation (NAO), wrote authors of a study published Thursday, Jan. 3, in Science Express, the online edition of the journal Science.

Winds that power the NAO are driven by atmospheric pressure differences between areas around Iceland and the Azores. â€œThe winds have a tremendous impact on the underlying ocean,â€ said Susan Lozier, a professor of physical oceanography at Dukeâ€™s Nicholas School of the Environment and Earth Sciences who is the studyâ€™s first author.

Other studies cited in the Science Express report suggest human-caused global warming may be affecting recent ocean heating trends. But Lozier and her coauthors found their data canâ€™t support that view for the North Atlantic. â€œIt is premature to conclusively attribute these regional patterns of heat gain to greenhouse warming,â€ they wrote.

â€œThe take-home message is that the NAO produces strong natural variability,â€ said Lozier in an interview. â€œThe simplistic view of global warming is that everything forward in time will warm uniformly. But this very strong natural variability is superimposed on human-caused warming. So researchers will need to unravel that natural variability to get at the part humans are responsible for.â€

In research supported by the National Science Foundation in the United States and the Natural Environment Research Council in the United Kingdom, her international team analyzed 50 years of North Atlantic temperature records collected at the National Oceanic Data Center in Washington, D.C.

To piece together the mechanisms involved in the observed changes, their analysis employed an ocean circulation model that predicts how winds, evaporation, precipitation and the exchange of heat with the atmosphere influences the North Atlanticâ€™s heat content over time. They also compared those computer predictions to real observations â€œto test the modelâ€™s skill,â€ the authors wrote.

Her groupâ€™s analysis showed that water in the sub-polar ocean â€“- roughly between 45 degrees North latitude and the Arctic Circle â€“- became cooler as the water directly exchanged heat with the air above it.

By contrast, NAO-driven winds served to â€œpile upâ€ sun-warmed waters in parts of the subtropical and tropical North Atlantic south of 45 degrees, Lozier said. That retained and distributed heat at the surface while pushing underlying cooler water further down.

The groupâ€™s computer model predicted warmer sea surfaces in the tropics and subtropics and colder readings within the sub-polar zone whenever the NAO is in an elevated state of activity. Such a high NAO has been the case during the years 1980 to 2000, the scientists reported.

â€œWe suggest that the large-scale, decadal changes…associated with the NAO are primarily responsible for the ocean heat content changes in the North Atlantic over the past 50 years,â€ the authors concluded.

However, the researchers also noted that this study should not be viewed in isolation. Given reported heat content gains in other oceans basins, and rising air temperatures, the authors surmised that other parts of the world’s ocean systems may have taken up the excess heat produced by global warming.

â€œBut in the North Atlantic, any anthropogenic (human-caused) warming would presently be masked by such strong natural variability,â€ they wrote.

Other authors of the report included Richard Williams and Vassil Roussenov of Liverpool University; Susan Leadbetter, previously at Liverpool University but now a postdoctoral researcher with Lozier; Mark Reed, a computational scientist who also works with Lozier at Duke; and Nathan Moore, a former Duke graduate student now at Michigan State University.

New MIT Study Validates Hurricane Prediction

admin — Mon, 20 Jul 2009 18:28:54 +0000

Provides confirmation that climate change intensifies storms

David Chandler, MIT News Office
April 17, 2008

Hurricanes in some areas, including the North Atlantic, are likely to become more intense as a result of global warming even though the number of such storms worldwide may decline, according to a new study by MIT researchers.

Kerry Emanuel, the lead author of the new study, wrote a paper in 2005 reporting an apparent link between a warming climate and an increase in hurricane intensity. That paper attracted worldwide attention because it was published in Nature just three weeks before Hurricane Katrina slammed into New Orleans.

Emanuel, a professor of atmospheric science in MIT’s Department of Earth, Atmospheric and Planetary Sciences, says the new research provides an independent validation of the earlier results, using a completely different approach. The paper was co-authored by postdoctoral fellow Ragoth Sundararajan and graduate student John Williams and appeared last week in the Bulletin of the American Meteorological Society.

While the earlier study was based entirely on historical records of past hurricanes, showing nearly a doubling in the intensity of Atlantic storms over the last 30 years, the new work is purely theoretical. It made use of a new technique to add finer-scale detail to computer simulations called Global Circulation Models, which are the basis for most projections of future climate change.

“It strongly confirms, independently, the results in the Nature paper,” Emanuel said. “This is a completely independent analysis and comes up with very consistent results.”

Worldwide, both methods show an increase in the intensity and duration of tropical cyclones, the generic name for what are known as hurricanes in the North Atlantic. But the new work shows no clear change in the overall numbers of such storms when run on future climates predicted using global climate models.

However, Emanuel says, the new work also raises some questions that remain to be understood. When projected into the future, the model shows a continuing increase in power, “but a lot less than the factor of two that we’ve already seen” he says. “So we have a paradox that remains to be explained.”

There are several possibilities, Emanuel says. “The last 25 years’ increase may have little to do with global warming, or the models may have missed something about how nature responds to the increase in carbon dioxide.”

Another possibility is that the recent hurricane increase is related to the fast pace of increase in temperature. The computer models in this study, he explains, show what happens after the atmosphere has stabilized at new, much higher CO₂ concentrations. “That’s very different from the process now, when it’s rapidly changing,” he says.

In the many different computer runs with different models and different conditions, “the fact is, the results are all over the place,” Emanuel says. But that doesn’t mean that one can’t learn from them. And there is one conclusion that’s clearly not consistent with these results, he said: “The idea that there is no connection between hurricanes and global warming, that’s not supported,” he says.

The work was partly funded by the National Science Foundation.

OffsetCarbonFootprint.org Library » North Atlantic

North Atlantic Warming Tied to Natural Variability

But global warming may be at play elsewhere in the world’s oceans, scientists surmise

New MIT Study Validates Hurricane Prediction

Provides confirmation that climate change intensifies storms

David Chandler, MIT News Office April 17, 2008

David Chandler, MIT News Office
April 17, 2008