Evidence for non-synchronous rotation of Europa
Non-synchronous rotation of Europa was predicted on theoretical grounds, by considering the orbitally averaged torque exerted by Jupiter on the satellite's tidal bulges. If Europa's orbit were circular, or the satellite were comprised of a frictionless fluid without tidal dissipation, this...
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Veröffentlicht in: | Nature (London) 1998-01, Vol.391 (6665), p.368-370 |
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Zusammenfassung: | Non-synchronous rotation of Europa was predicted on theoretical grounds, by considering the orbitally averaged torque exerted by Jupiter
on the satellite's tidal bulges. If Europa's orbit were circular, or the satellite
were comprised of a frictionless fluid without tidal dissipation, this torque
would average to zero. However, Europa has a small forced eccentricity
e 0.01 (ref. 2), generated by
its dynamical interaction with Io and Ganymede, which should cause the equilibrium
spin rate of the satellite to be slightly faster than synchronous. Recent
gravity data suggest that there may be a permanent asymmetry
in Europa's interior mass distribution which is large enough to offset the
tidal torque; hence, if non-synchronous rotation is observed, the surface
is probably decoupled from the interior by a subsurface layer of liquid or ductile ice. Non-synchronous rotation was invoked
to explain Europa's global system of lineaments and an equatorial region of
rifting seen in Voyager images,. Here we report
an analysis of the orientation and distribution of these surface features,
based on initial observations made by the Galileo spacecraft. We find evidence
that Europa spins faster than the synchronous rate (or did so in the past),
consistent with the possibility of a global subsurface ocean. |
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ISSN: | 0028-0836 1476-4687 |
DOI: | 10.1038/34869 |