Physics of bodily tides in terrestrial planets and the appropriate scales of dynamical evolution

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Read Full Article (file size: 6029862 bytes) Cited by JOURNAL OF GEOPHYSICAL RESEARCH, VOL. 112, E12003, doi:10.1029/2007JE002908, 2007 Physics of bodily tides in terrestrial planets and the appropriate scales of dynamical evolution Michael Efroimsky U.S. Naval Observatory, Washington, D. C., USA Valéry Lainey IMCCE-Observatoire de Paris, UMR 8028 du CNRS, Paris, France Observatoire Royal de Belgique, Brussels, Belgium Abstract Any model of tides is based on a specific hypothesis of how lagging depends on the tidal-flexure frequency χ. For example, Gerstenkorn (1955), MacDonald (1964), and Kaula (1964) assumed constancy of the geometric lag angle δ, while Singer (1968) and Mignard (1979, 1980) asserted constancy of the time lag Δt. Thus each of these two models was based on a certain law of scaling of the geometric lag: the Gerstenkorn-MacDonald-Kaula theory implied that δ ∼ χ ⁰, while the Singer-Mignard theory postulated δ ∼ χ ¹. The actual dependence of the geometric lag on the frequency is more complicated and is determined by the rheology of the planet. Besides, each particular functional form of this dependence will unambiguously fix the appropriate form of the frequency dependence of the tidal quality factor, Q(χ). Since at present we know the shape of the function Q(χ), we can reverse our line of reasoning and single out the appropriate actual frequency dependence of the lag, δ(χ): as within the frequency range of our concern Q ∼ χ ^α, α = 0.2–0.4, then δ ∼ χ ^−α. This dependence turns out to be different from those employed hitherto, and it entails considerable alterations in the timescales of the tide-generated dynamical evolution. Phobos's fall on Mars is an example we consider. Received 15 February 2007; accepted 12 October 2007; published 29 December 2007. Keywords: bodily tides; body tides; land tides; satellites; terrestrial planers; Mars. Index Terms: 7504 Solar Physics, Astrophysics, and Astronomy: Celestial mechanics; 5144 Physical Properties of Rocks: Wave attenuation; 6225 Planetary Sciences: Solar System Objects: Mars; 6230 Planetary Sciences: Solar System Objects: Martian satellites; 5460 Planetary Sciences: Solid Surface Planets: Physical properties of materials. Read Full Article (file size: 6029862 bytes) Cited by Citation: Efroimsky, M., and V. Lainey (2007), Physics of bodily tides in terrestrial planets and the appropriate scales of dynamical evolution, J. Geophys. Res., 112, E12003, doi:10.1029/2007JE002908. This paper is not subject to U.S. copyright. Published in 2007 by the American Geophysical Union.

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