Warmer than a
Hot Tub: Atlantic Ocean Temperatures Much Higher in the Past
February 17, 2006 — By Woods Hole Oceanographic Institution
FALMOUTH, Mass. — Scientists have found evidence that tropical Atlantic Ocean
temperatures may have once reached 107°F (42°C)-about 25°F (14°C) higher than
ocean temperatures today and warmer than a hot tub. The surprisingly high ocean
temperatures, the warmest estimates to date for any place on Earth, occurred
millions of year ago when carbon dioxide levels in Earth's atmosphere were also
high, but researchers say they may be an indication that greenhouse gases could
heat the oceans in the future much more than currently anticipated. The study
suggests that climate models underestimate future warming.
"These temperatures are off the charts from what we've seen before," said Karen
Bice, a paleoclimatologist at Woods Hole Oceanographic Institution (WHOI). Bice
reported the findings today at the annual meeting of the American Association
for the Advancement of Science (AAAS) in St. Louis and is also lead author of a
study to be published in an upcoming issue of the journal Paleoceanography,
published by the American Geophysical Union.
Bice and a multi-institutional team of scientists studied three long columns of
sediment cored from the seafloor in 2003 off Suriname, on the northeast coast of
South America, by the drillship JOIDES Resolution, operated by the international
Ocean Drilling Program.
The sediments contained an unusually rich and well-preserved accumulation of
both carbon-rich organic matter and the fossilized shells of microscopic marine
organisms that had settled and piled up on the seafloor over tens of millions of
years. The deeper down in the core the scientists analyzed, the further back in
time they went.
The team analyzed the shells' isotopic and trace element chemistry, which
changes along with temperature changes in the surface waters where they lived.
They determined that ocean temperatures in the region ranged between 91° and
107°F (33° and 42°C) between 84 million and 100 million years ago in an era when
dinosaurs roamed the Earth. Temperatures range between 75° and 82°F (24° and
28°C) in the same region now. The approximate uncertainty in the
paleotemperature estimates is +/-2°C.
Using organic matter from the sediments, the group also estimated atmospheric
carbon dioxide concentrations during the same time span. They were 1,300 to
2,300 parts per million (ppm), compared with 380 ppm today.
The findings, if confirmed, create a dilemma for scientists seeking to forecast
how Earth's climate and environment will change in response to the rising
amounts of heat-trapping carbon dioxide in the atmosphere, caused by
deforestation and the burning of oil, coal, and other fossil fuels. When 1,300
to 2,300 ppm of carbon dioxide is factored into current computer models that
simulate global climate, it does not produce such high ocean temperatures.
"The climate models underestimate temperatures and the amount of warming that
would accompany an increase in CO2 of more than 1,000 ppm above
today's level." Bice said.
If the scientists' interpretations of past ocean temperatures and carbon dioxide
levels prove accurate, actual future warming from elevated atmospheric carbon
dioxide concentrations may be much greater than predicted by the models, the
scientists reported.
"One of the most important impacts this evidence suggests is the change to the
Earth's hydrologic cycle," Bice said. "Higher tropical temperatures will
increase the intensity of hurricanes and winter storms. In addition,
precipitation patterns will change, moving even more rain that now falls on the
central U.S. - an area known as the breadbasket of the U.S. for its food
production - to higher latitudes where the quality of the soil may not be as
conducive to agriculture"
"Policymakers use these models to predict likely climate change with increasing
CO2 levels, and if the models are not right, society is not well
informed or well served."
Alternatively, the models used to predict future climate may be missing a
critical factor that amplifies heating, Bice said. During past warm periods,
oceans and wetlands may have released much more methane gas to the atmosphere.
Methane traps heat 10 times more effectively than carbon dioxide.
However, extraordinarily high concentrations of methane in the model still fail
to produce the tropical Atlantic and Arctic Ocean temperatures inferred for 91
million years ago. This supports the idea that the model's response to increased
greenhouse gas concentrations underestimates the actual climate system's
response.
The research team included Bice and Kristina Dahl of WHOI, Philip A. Meyers of
the University of Michigan, Daniel Birgel and Kai-Uwe Hinrichs of the University
of Bremen, and Richard D. Norris of Scripps Institution of Oceanography. Bice's
work was supported by private funding from the Woods Hole Oceanographic
Institution through the Ocean and Climate Change Institute and The Andrew W.
Mellon Foundation Endowed Fund for Innovative Research. Funding for this
research was also provided by the Joint Oceanographic Institutions U.S. Science
Support Program and Deutsche Forschungsgemeinschaft through the DFG-Research
Center Ocean Margins.
Contact Info:
Shelley Dawicki
Media Relations Office
508-289-2270 or 33400
sdawicki@whoi.edu
Website :
Woods Hole Oceanographic Institution