Abstract
Palaeomagnetic data suggest that the Earth was glaciated at low latitudes during the Palaeoproterozoic1,2 (about 2.4–2.2 Gyr ago) and Neoproterozoic3,4,5,6,7,8 (about 820–550 Myr ago) eras, although some of the Neoproterozoic data are disputed9,10. If the Earth's magnetic field was aligned more or less with its spin axis, as it is today, then either the polar ice caps must have extended well down into the tropics — the ‘snowball Earth’ hypothesis8 — or the present zonation of climate with respect to latitude must have been reversed. Williams11 has suggested that the Earth's obliquity may have been greater than 54° during most of its history, which would have made the Equator the coldest part of the planet12. But this would require a mechanism to bring the obliquity down to its present value of 23.5°. Here we propose that obliquity–oblateness feedback13 could have reduced the Earth's obliquity by tens of degrees in less than 100 Myr if the continents were situated so as to promote the formation of large polar ice sheets. A high obliquity for the early Earth may also provide a natural explanation for the present inclination of the lunar orbit with respect to the ecliptic (5°), which is otherwise difficult to explain.
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Acknowledgements
We thank H. Levison and M. Duncan for the orbital integration code (SWIFT) and J. Laskar for the code used to integrate the precession equations. We also acknowledge discussions with J.Melosh and R. Canup concerning the lunar inclination. D.M.W. was supported by a NASA graduate student research fellowship awarded in 1995, and J.F.K. was supported by the NASA Exobiology Program.
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Williams, D., Kasting, J. & Frakes, L. Low-latitude glaciation and rapid changes in the Earth's obliquity explained by obliquity–oblateness feedback. Nature 396, 453–455 (1998). https://doi.org/10.1038/24845
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DOI: https://doi.org/10.1038/24845
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