Orbital effects of spatial variations of fundamental coupling constants

Abstract

We deal with the effects induced on the orbit of a test particle revolving around a central body by putative spatial variations of fundamental coupling constants ζ. In particular, we assume a dipole gradient for ζ( r)/ζ along a generic direction k in space. We analytically work out the long-term variations of all the six standard Keplerian orbital elements parameterizing the orbit of a test particle in a gravitationally bound two-body system. It turns out that, apart from the semi-major axis a, the eccentricity e, the inclination I, the longitude of the ascending node , the longitude of pericenter π and the mean anomaly M undergo non-zero long-term changes. By using the usual decomposition along the radial (R), transverse (T) and normal (N) directions, we also analytically work out the long-term changes R, T, N and vR, vT, vN experienced by the position and the velocity vectors r and v of the test particle. It turns out that, apart from N, all the other five shifts do not vanish over one full orbital revolution. In the calculation we do not use a-priori simplifying assumptions concerning e and I. Thus, our results are valid for a generic orbital geometry; moreover, they hold for any gradient direction (abridged).