Spatial patterns of tidal heating

► The angular distribution of tidal heating is a linear combination of three basic patterns. ► Each pattern depends on the tidal potential while its weight depends on the internal structure. ► A first type of pattern is due to mantle dissipation. ► Two other types of patterns are due to dissipation...

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Bibliographic Details
Published in:Icarus (New York, N.Y. 1962) N.Y. 1962), 2013-03, Vol.223 (1), p.308-329
Main Author: Beuthe, Mikael
Format: Article
Language:English
Subjects:
Dissipation
Europa
Heating
Liquids
Mantle
Mathematical models
Planetary dynamics
Thin walled shells
Tidal effects
Tides
Tides, Solid body
Titan
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Summary:► The angular distribution of tidal heating is a linear combination of three basic patterns. ► Each pattern depends on the tidal potential while its weight depends on the internal structure. ► A first type of pattern is due to mantle dissipation. ► Two other types of patterns are due to dissipation in a thin or thick soft layer. ► The pattern in a thin floating icy shell is independent of rheology. In a body periodically strained by tides, heating produced by viscous friction is far from homogeneous. The spatial distribution of tidal heating depends in a complicated way on the tidal potential and on the internal structure of the body. I show here that the distribution of the dissipated power within a spherically stratified body is a linear combination of three angular functions. These angular functions depend only on the tidal potential whereas the radial weights are specified by the internal structure of the body. The 3D problem of predicting spatial patterns of dissipation at all radii is thus reduced to the 1D problem of computing weight functions. I compute spatial patterns in various toy models without assuming a specific rheology: a viscoelastic thin shell stratified in conductive and convective layers, an incompressible homogeneous body and a two-layer model of uniform density with a liquid or rigid core. For a body in synchronous rotation undergoing eccentricity tides, dissipation in a mantle surrounding a liquid core is highest at the poles. Within a soft layer (or asthenosphere) in contact with a more rigid layer, the same tides generate maximum heating in the equatorial region with a significant degree-four structure if the soft layer is thin. The asthenosphere can be a layer of partial melting in the upper mantle or, very differently, an icy layer in contact with a silicate mantle or solid core. Tidal heating patterns are thus of three main types: mantle dissipation (with the icy shell above an ocean as a particular case), dissipation in a thin soft layer and dissipation in a thick soft layer. Finally, I show that the toy models predict well patterns of dissipation in Europa, Titan and Io. The formalism described in this paper applies to dissipation within solid layers of planets and satellites for which internal spherical symmetry and viscoelastic linear rheology are good approximations.
ISSN:0019-1035
1090-2643
DOI:10.1016/j.icarus.2012.11.020