The Earth underwent several snowball glaciations between 1,000 and 542 million years ago. The termination of these glaciations is thought to have been triggered by the accumulation of volcanic CO(2) in the atmosphere over millions of years(1,2). Subsequent high temperatures and loss of continental ice would increase silicateweathering and in turn drawdown atmospheric CO(2) (ref. 3). Estimates of the post-snowballweathering rate indicate that equilibrium between CO(2) input and removal would be restored within several million years(4), potentially triggering a new glaciation. However the transition between deglaciation and the onset a new glaciation was on the order of 10(7) years. Over long timescales, the availability of fresh rock can become a limiting factor for silicate weathering rates(5). Here we show that when this transport-determined limitation is incorporated into the COPSE biogeochemical model(6), the stabilization time is substantially longer, > 10(7) years. When we include a simple ice-albedo feedback, the model produces greenhouse-icehouse oscillations on this timescale that are compatible with observations. Our simulations also indicate positive carbon isotope excursions and an increased flux of oxygen to the atmosphere during interglacials, both of which are consistent with the geological record(7,8). We conclude that the long gaps between snowball glaciations can be explained by limitations on silicate weathering rates.

• 出版日期2011-12