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Mapping Solar System chaos with the Geological Orrery

Mapping Solar System chaos with the Geological Orrery
Mapping Solar System chaos with the Geological Orrery
The Geological Orrery is a network of geological records of orbitally paced climate designed to address the inherent limitations of solutions for planetary orbits beyond 60 million years ago due to the chaotic nature of Solar System motion. We use results from two scientific coring experiments in Early Mesozoic continental strata: the Newark Basin Coring Project and the Colorado Plateau Coring Project. We precisely and accurately resolve the secular fundamental frequencies of precession of perihelion of the inner planets and Jupiter for the Late Triassic and Early Jurassic epochs (223–199 million years ago) using the lacustrine record of orbital pacing tuned only to one frequency (1/405,000 years) as a geological interferometer. Excepting Jupiter’s, these frequencies differ significantly from present values as determined using three independent techniques yielding practically the same results. Estimates for the precession of perihelion of the inner planets are robust, reflecting a zircon U–Pb-based age model and internal checks based on the overdetermined origins of the geologically measured frequencies. Furthermore, although not indicative of a correct solution, one numerical solution closely matches the Geological Orrery, with a very low probability of being due to chance. To determine the secular fundamental frequencies of the precession of the nodes of the planets and the important secular resonances with the precession of perihelion, a contemporaneous high-latitude geological archive recording obliquity pacing of climate is needed. These results form a proof of concept of the Geological Orrery and lay out an empirical framework to map the chaotic evolution of the Solar System.
0027-8424
10664-10673
Olsen, Paul E.
bdbec40b-82ed-41ac-8028-b6c333206f16
Laskar, Jacques
e8c93d35-c751-4939-aaa6-5288fb841415
Kent, Dennis V.
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Kinney, Sean T.
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Reynolds, David J.
7761a0ea-0758-4410-8ce0-048db979902e
Sha, Jingeng
d1a4e47e-1ef1-44e7-a48c-d0bc2f2e67fc
Whiteside, Jessica H.
5d9ad7aa-eba3-4ad9-9f6f-81be71b6829b
Olsen, Paul E.
bdbec40b-82ed-41ac-8028-b6c333206f16
Laskar, Jacques
e8c93d35-c751-4939-aaa6-5288fb841415
Kent, Dennis V.
8d441507-6a10-4db7-8d28-db17ccb9fb69
Kinney, Sean T.
95ed03b7-7a8f-4a2e-b433-0059db95e1e1
Reynolds, David J.
7761a0ea-0758-4410-8ce0-048db979902e
Sha, Jingeng
d1a4e47e-1ef1-44e7-a48c-d0bc2f2e67fc
Whiteside, Jessica H.
5d9ad7aa-eba3-4ad9-9f6f-81be71b6829b

Olsen, Paul E., Laskar, Jacques, Kent, Dennis V., Kinney, Sean T., Reynolds, David J., Sha, Jingeng and Whiteside, Jessica H. (2019) Mapping Solar System chaos with the Geological Orrery. Proceedings of the National Academy of Sciences of the United States of America, 116 (22), 10664-10673. (doi:10.1073/pnas.1813901116).

Record type: Article

Abstract

The Geological Orrery is a network of geological records of orbitally paced climate designed to address the inherent limitations of solutions for planetary orbits beyond 60 million years ago due to the chaotic nature of Solar System motion. We use results from two scientific coring experiments in Early Mesozoic continental strata: the Newark Basin Coring Project and the Colorado Plateau Coring Project. We precisely and accurately resolve the secular fundamental frequencies of precession of perihelion of the inner planets and Jupiter for the Late Triassic and Early Jurassic epochs (223–199 million years ago) using the lacustrine record of orbital pacing tuned only to one frequency (1/405,000 years) as a geological interferometer. Excepting Jupiter’s, these frequencies differ significantly from present values as determined using three independent techniques yielding practically the same results. Estimates for the precession of perihelion of the inner planets are robust, reflecting a zircon U–Pb-based age model and internal checks based on the overdetermined origins of the geologically measured frequencies. Furthermore, although not indicative of a correct solution, one numerical solution closely matches the Geological Orrery, with a very low probability of being due to chance. To determine the secular fundamental frequencies of the precession of the nodes of the planets and the important secular resonances with the precession of perihelion, a contemporaneous high-latitude geological archive recording obliquity pacing of climate is needed. These results form a proof of concept of the Geological Orrery and lay out an empirical framework to map the chaotic evolution of the Solar System.

Text
Olsen et al 2019 Orrery PNAS post-review submission - Accepted Manuscript
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Accepted/In Press date: 31 January 2019
e-pub ahead of print date: 4 March 2019
Published date: 28 May 2019

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Local EPrints ID: 428941
URI: http://eprints.soton.ac.uk/id/eprint/428941
ISSN: 0027-8424
PURE UUID: e4e6c945-29d1-4f63-a84c-1b03c60b6c8f

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Date deposited: 15 Mar 2019 17:30
Last modified: 16 Mar 2024 00:53

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Contributors

Author: Paul E. Olsen
Author: Jacques Laskar
Author: Dennis V. Kent
Author: Sean T. Kinney
Author: David J. Reynolds
Author: Jingeng Sha

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