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On computing viscoelastic Love numbers for general planetary models: the texttt{ALMA{}³} code

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arxiv 2301.07351 v1 pith:J4YDVYSG submitted 2023-01-18 astro-ph.EP physics.geo-ph

On computing viscoelastic Love numbers for general planetary models: the texttt{ALMA{}³} code

classification astro-ph.EP physics.geo-ph
keywords lovenumbersplanetaryviscoelasticadoptingalmaearthfrequency-dependent
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The computation of the Love numbers for a spherically symmetric self-gravitating viscoelastic Earth is a classical problem in global geodynamics. Here we revisit the problem of the numerical evaluation of loading and tidal Love numbers in the static limit for an incompressible planetary body, adopting a Laplace inversion scheme based upon the Post-Widder formula as an alternative to the {traditional viscoelastic normal modes method. We also consider, whithin the same framework, complex-valued, frequency-dependent Love numbers that describe the response to a periodic forcing, which are paramount in the study of the tidal deformation of planets. Furthermore, we numerically obtain the time-derivatives of Love numbers, suitable for modeling geodetic signals in response to surface loads variations. A number of examples are shown, in which time and frequency-dependent Love numbers are evaluated for the Earth and planets adopting realistic rheological profiles. The numerical solution scheme is implemented in ALMA${}^3$ (the plAnetary Love nuMbers cAlculator, version 3), an upgraded open-source Fortran 90 program that computes the Love numbers for radially layered planetary bodies with a wide range of rheologies, including transient laws like Andrade or Burgers.

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