In this week's issue of Science (Science 11 January 2008:Vol. 319. no. 5860, p. 145), paleoceanographers present new data that make the case for polar ice at the height of the Cretaceous hothouse 90 million years ago.
The study by researchers at Scripps Institution of Oceanography at UC San Diego provides strong evidence that a glacial antarctic ice cap, about half the size (until 60%) of the modern day glacial ice sheet, existed 91 million years ago during a period of high mean global temperatures.
The new study is titled, “Isotopic Evidence for Glaciation During the Cretaceous Supergreenhouse,” and examines geochemical and sea level data retrieved from marine microfossils deposited on the ocean floor 91 million years ago during the Cretaceous Thermal Maximum.
This extreme warming event in Earth’s history raised tropical ocean temperatures to 35-37°C, about 10°C warmer than today, thus creating an intense greenhouse climate. But 90 milion years ago the sealevel dropped worldwide by 40 m - how, and why?
Using two independent isotopic techniques, researchers at Scripps Oceanography studied the microfossils to gather geochemical data on the growth and eventual melting of large Cretaceous ice sheets (Stable isotopes of oxygen molecules (d18O) in bottom-dwelling and near-surface marine foraminifera as proxy for large waterstorages other than the oceans, and the chemical composition of fossil archeobacteria-membranes as proxy for water-temperatures).
These independent methods provided Andre Bornemann, lead author of the study, with strong evidence to conclude that an ice sheet about 50-60 percent the size of the modern Antarctic ice cap existed for about 200,000 years. Bornemann conducted this study as a postdoctoral researcher at Scripps Oceanography and continues this research at Universitat Leipzig in Germany.
“Until now it was generally accepted that there were no large glaciers on the poles prior to the development of the Antarctic ice sheet about 33 million years ago,” said Richard Norris, professor of paleobiology at Scripps Oceanography and co-author of the study. “This study demonstrates that even the super-warm climates of the Cretaceous Thermal Maximum were not warm enough to prevent ice growth.”
Researchers are still unclear as to where such a large mass of ice could have existed in the Cretaceous or how ice growth could have started. The temperatures where much to high for icefields in or on the oceans. So the authors suggest that climate cycles may have favored ice growth during a few times in the Cretaceous when natural climate variations produced unusually cool summers, likewise on high mountains or on the continent of Antarctica.
But anyway ice sheets were much less common during the Cretaceous Thermal Maximum than during more recent “icehouse” climates. Paradoxically, past greenhouse climates may have aided ice growth by increasing the amount of moisture in the atmosphere and creating more winter snowfall at high elevations and high latitudes, according to the paper’s authors.
The results from the study are consistent with other studies from Russia and New Jersey that show sea level fell by about 25-40 m at the same time that the ice sheets were growing during the Cretaceous period. Sea level is known to fall as water is removed from the oceans to build continental ice sheets; conversely, sea level rises as ice melts and returns to the sea.
The presence or absence of sea ice has major environmental implications, specifically in terms of sea level rise and global circulation patterns.
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