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Published December 2021 | Published + Supplemental Material
Journal Article Open

Long-Term Earth-Moon Evolution With High-Level Orbit and Ocean Tide Models

Daher, Houraa ORCID icon
Arbic, Brian K. ORCID icon
Williams, James G. ORCID icon
Ansong, Joseph K. ORCID icon
Boggs, Dale H. ORCID icon
Müller, Malte ORCID icon
Schindelegger, Michael ORCID icon
Austermann, Jacqueline ORCID icon
Cornuelle, Bruce D. ORCID icon
Crawford, Eliana B. ORCID icon
Fringer, Oliver B. ORCID icon
Lau, Harriet C. P. ORCID icon
Lock, Simon J. ORCID icon
Maloof, Adam C. ORCID icon
Menemenlis, Dimitris ORCID icon
Mitrovica, Jerry X. ORCID icon
Green, J. A. Mattias ORCID icon
Huber, Matthew ORCID icon

Abstract

Tides and Earth-Moon system evolution are coupled over geological time. Tidal energy dissipation on Earth slows Earth's rotation rate, increases obliquity, lunar orbit semi-major axis and eccentricity, and decreases lunar inclination. Tidal and core-mantle boundary dissipation within the Moon decrease inclination, eccentricity and semi-major axis. Here we integrate the Earth-Moon system backwards for 4.5 Ga with orbital dynamics and explicit ocean tide models that are "high-level" (i.e., not idealized). To account for uncertain plate tectonic histories, we employ Monte Carlo simulations, with tidal energy dissipation rates (normalized relative to astronomical forcing parameters) randomly selected from ocean tide simulations with modern ocean basin geometry and with 55, 116, and 252 Ma reconstructed basin paleogeometries. The normalized dissipation rates depend upon basin geometry and Earth's rotation rate. Faster Earth rotation generally yields lower normalized dissipation rates. The Monte Carlo results provide a spread of possible early values for the Earth-Moon system parameters. Of consequence for ocean circulation and climate, absolute (un-normalized) ocean tidal energy dissipation rates on the early Earth may have exceeded today's rate due to a closer Moon. Prior to ~3 Ga, evolution of inclination and eccentricity is dominated by tidal and core-mantle boundary dissipation within the Moon, which yield high lunar orbit inclinations in the early Earth-Moon system. A drawback for our results is that the semi-major axis does not collapse to near-zero values at 4.5 Ga, as indicated by most lunar formation models. Additional processes, missing from our current efforts, are discussed as topics for future investigation.

Additional Information

© 2021. The Authors. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. Issue Online: 01 December 2021; Version of Record online: 01 December 2021; Accepted manuscript online: 23 September 2021; Manuscript accepted: 14 September 2021; Manuscript revised: 26 August 2021; Manuscript received: 22 February 2021. We thank Mathieu Dumberry (who pointed out the time variable nature of K_(moon)/C_(moon)), Luc Lourens (who pointed out the need to discuss ice caps more thoroughly), an anonymous reviewer (who helped trim manuscript length), and the editor (Laurent Montesi) for helpful comments. B. K. Arbic thanks Robert Krasny for early discussions about orbital model time-stepping, Richard Ray for information on small tidal constituents, Chris Garrett for comments on tidal resonance, Dudley Chelton for useful comments on writing, and Stephen Meyers for discussions on precession rates in Meyers and Malinverno (2018, their Table 2). B. K. Arbic and M. Schindelegger thank Robert Hallberg for discussions on energy dissipation rates due to bed friction in ocean models. Much of B. K. Arbic's contributions to this study took place while he was on sabbatical in France. B. K. Arbic thanks many French colleagues, especially Thierry Penduff, Rosemary Morrow, Nadia Ayoub, and Florent Lyard, for their help in procuring this sabbatical year. J. K. Ansong and B. K. Arbic thank Alistair Adcroft for help in setting up MOM6, and funding from the University of Michigan Associate Professor Support Fund, supported by the Margaret and Herman Sokol Faculty Awards. J. K. Ansong, H. Daher, E. B. Crawford, and B. K. Arbic acknowledge National Science Foundation (NSF) grants OCE-0968783 and OCE-1351837, including Research Experience for Undergraduates (REU) supplements for H. Daher and E. B. Crawford. B. K. Arbic additionally acknowledges NASA grants NNX16AH79G, NNX17AH55G, and 80NSSC20K1135. M. Schindelegger acknowledges Austrian Science Fund (FWF) for grant P30097-N29. S. J. Lock acknowledges NSF grant EAR-1947614. J. X. Mitrovica was supported by Harvard University and NASA grant NNX17AE42G. J. A. M. Green acknowledges the UK's Natural Environment Research Council, grant NE/S009566/1 (MATCH). A portion of the research described in this study was carried out at the Jet Propulsion Laboratory of the California Institute of Technology, under a contract with the National Aeronautics and Space Administration (80NM0018D0004). Government sponsorship is acknowledged. B. K. Arbic dedicates his contributions to the work presented here to his beloved brother Joel Bernard Arbic, who passed away on December 2, 2017. Joel was passionate about a great many things, especially travel, adventure, family, and friends, and tremendously gifted in ways his older brother Brian was not, especially in endeavors mechanical, athletic, and artistic. Joel will forever be missed by his wife, two sons, parents, two brothers, in-laws, two nieces, other relatives, and numerous friends around the world. Data Availability Statement: The MOM6 simulations used in early drafts of this study were carried out on the Flux supercomputer provided by the University of Michigan Advanced Research Computing Technical Services. Computational resources for the main ocean tide simulations used in this work were provided by the Vienna Scientific Cluster (VSC) and the NASA High-End Computing (HEC) Program through the NASA Advanced Supercomputing (NAS) Division at Ames Research Center. Data sufficient to make Figures 1 and 4-11, the 24 hr results in Figures 2 and 3, and Figures S1 and S2 are provided in Arbic and Schindelegger (2021). A subset of the computational code used in this paper is also provided in Arbic and Schindelegger (2021).

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Published - 2021JE006875.pdf

Supplemental Material - 2021je006875-sup-0001-supporting_information_si-s01.pdf

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Additional details

Identifiers Funding Dates
Created:
August 22, 2023
Modified:
October 23, 2023