Gauss's Law and the Source for Poisson's Equation in Modified Gravity with Varying G

Abstract

We have recently shown that the baryonic Tully-Fisher and Faber-Jackson relations imply that the gravitational "constant" G in the force law varies with acceleration a as G 1/a and vice versa. These results prompt us to reconsider every facet of Newtonian dynamics. Here we show that the integral form of Gauss's law in spherical symmetry remains valid in G(a) gravity, but the differential form depends on the precise distribution of G(a)M(r), where r is the distance from the origin and M(r) is the mass distribution. We derive the differential form of Gauss's law in spherical symmetry, thus the source for Poisson's equation as well. Modified Newtonian dynamics (MOND) and weak-field Weyl gravity are asymptotic limits of G(a) gravity at low and high accelerations, respectively. In these limits, we derive telling approximations to the source in spherical symmetry. It turns out that the source has a strong dependence on surface density M/r2 everywhere in a-space except in the deep Newton-Weyl regime of very high accelerations.