Interior potential of a toroidal shell from pole values
Abstract
We have investigated the toroidal analog of ellipsoidal shells of matter, which are of great significance in Astrophysics. The exact formula for the gravitational potential of a shell with a circular section at the pole of toroidal coordinates is first established. It depends on the mass of the shell, its main radius and axis-ratio (i.e. core-to-main radius ratio), and involves the product of the complete elliptic integrals of the first and second kinds. Next, we show that successive partial derivatives are also accessible by analytical means at that singular point, thereby enabling the expansion of the interior potential as a bivariate series. Then, we have generated approximations at orders , , and , corresponding to increasing accuracy. Numerical experiments confirm the great reliability of the approach, in particular for small-to-moderate axis ratios ( typically). In contrast with the ellipsoidal case (Newton's theorem), the potential is not uniform inside the shell cavity as a consequence of the curvature. We explain how to construct the interior potential of toroidal shells with a thick edge (i.e. tubes), and how a core stratification can be accounted for. This is a new step towards the full description of the gravitating potential and forces of tori and rings. Applications also concern electrically-charged systems, and thus go beyond the context of gravitation.
Cite
@article{arxiv.1905.01913,
title = {Interior potential of a toroidal shell from pole values},
author = {J. -M. Huré and A. Trova and V. Karas and C. Lesca and Univ. Bordeaux and France and CNRS-LAB and France and University of Bremen and Center of Applied Space Technology and Microgravity and Germany and Astronomical Institute and Academy of Sciences and Czech Republic},
journal= {arXiv preprint arXiv:1905.01913},
year = {2019}
}
Comments
Accepted for publication in MNRAS