Geological and geochemical evidence(1-3) indicates that the Antarctic ice sheet formed during the Eocene-Oligocene transition(4), 33.5-34.0 million years ago. Modelling studies(5,6) suggest that such ice-sheet formation might have been triggered when atmospheric carbon dioxide levels (p(CO2)(atm)) fell below a critical threshold of similar to 750 p. p. m. v., but the timing and magnitude of p(CO2)(atm) relative to the evolution of the ice sheet has remained unclear. Here we use the boron isotope pH proxy(7,8) on exceptionally well-preserved carbonate microfossils from a recently discovered geological section in Tanzania(9,10) to estimate p(CO2)(atm) before, during and after the climate transition. Our data suggest that a reduction in p(CO2)(atm) occurred before the main phase of ice growth, followed by a sharp recovery to pre-transition values and then a more gradual decline. During maximum ice-sheet growth, p(CO2)(atm) was between similar to 450 and similar to 1,500 p. p. m. v., with a central estimate of similar to 760 p. p. m. v. The ice cap survived the period of p(CO2)(atm) recovery, although possibly with some reduction in its volume, implying (as models predict(11)) a nonlinear response to climate forcing during melting. Overall, our results confirm the central role of declining p(CO2)(atm) in the development of the Antarctic ice sheet (in broad agreement with carbon cycle modelling(12)) and help to constrain mechanisms and feedbacks associated with the Earth's biggest climate switch of the past 65 Myr.

• 出版日期2009-10-22