The Earths long-term climate changes and ice ages: a derivation of Milankovitch cycles from first principles
Long-term changes in the tilt of the Earths axis, relative to the plane of its orbit, are of great significance to long-term climate change, because they control the size of the arctic and antarctic circles. These Milankovitch cycles have generally been calculated by numerical integration of Newtons...
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Format: | Article in Journal/Newspaper |
Language: | unknown |
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arXiv
2020
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Online Access: | https://dx.doi.org/10.48550/arxiv.2011.03985 https://arxiv.org/abs/2011.03985 |
Summary: | Long-term changes in the tilt of the Earths axis, relative to the plane of its orbit, are of great significance to long-term climate change, because they control the size of the arctic and antarctic circles. These Milankovitch cycles have generally been calculated by numerical integration of Newtons equations of motion, and there is some controversy over the results because they are sensitive to numerical drift over the very long computer simulations involved. In this paper the cycles are calculated from first principles, without any reliance on computer simulation. The problem is one of planetary precession, and is solvable by the methods used to study the precession of a spinning top. It is shown that the main component of Milankovitch cycles has a period of 41,000 years and is due to one of the modes of precession of the Earth-Venus system. The other mode of this system produces a component of period 29,500 years, and a third component of period 54,000 years results from the influence of the precession of the orbits of Jupiter and Saturn. These results agree closely with several of the numerical simulations in the literature, and strongly suggest that other different results in the literature are incorrect. : 24 pages, 7 figures. Conclusions revised in light of comments received, see Acknowledgements. Submitted to American Journal of Physics. Converted to LaTeX with minor corrections. Shortened version (omitting Sections III - V and Appendices) re-submitted to American Journal of Physics |
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