Precession Relaxation of Viscoelastic Oblate Rotators

TL;DR

This paper develops a rheology-based model for nutation relaxation in viscoelastic oblate rotators, providing a more accurate and shape-dependent description of spin damping timescales than traditional empirical methods.

Contribution

It introduces a rheology-derived approach to nutation damping that depends on current nutation angle, shape, and material properties, improving upon empirical Q-factor models.

Findings

Damping rate depends on nutation angle, shape, and rheology.

Zero damping in the spherical shape limit.

Applicable to any linear rheological law and shape.

Abstract

Perturbations of all sorts destabilise the rotation of a small body and leave it in a non-principal spin state. In such a state, the body experiences alternating stresses generated by the inertial forces. This yields nutation relaxation, i.e., evolution of the spin towards the principal rotation about the maximal-inertia axis. Knowledge of the timescales needed to damp the nutation is crucial in studies of small bodies' dynamics. In the literature hitherto, nutation relaxation has always been described with aid of an empirical quality factor $\,Q\,$ introduced to parameterise the energy dissipation rate. Among the drawbacks of this approach was its inability to describe the dependence of the relaxation rate upon the current nutation angle. This inability stemmed from our lack of knowledge of the quality factor's dependence on the forcing frequency. In this article, we derive our description of nutation damping directly from the rheological law obeyed by the material. This renders us the nutation damping rate as a function of the current nutation angle, as well as of the shape and the rheological parameters of the body. In contradistinction from the approach based on an empirical $\,Q\,$-factor, our development gives a zero damping rate in the spherical-shape limit. Our method is generic and applicable to any shape and to any linear rheological law. However, to simplify the developments, here we consider a dynamically oblate rotator with a Maxwell rheology.