From planes to spheres: About gravitational lens magnifications

TL;DR

This paper extends gravitational lensing theory from planes to spheres, resolving a paradox about magnification and flux conservation by introducing a modified Poisson equation on the sphere.

Contribution

It develops a spherical formalism for gravitational lensing, including a modified Poisson equation, to ensure flux conservation and clarify the relation between magnification and flux.

Findings

Magnification can be below unity far from the optical axis.

The formalism ensures total photon number conservation on a sphere.

Surface brightness is not strictly conserved due to reciprocity law.

Abstract

We discuss the classic theorem according to which a gravitational lens always produces a total magnification greater than unity. This theorem seems to contradict the conservation of total flux from a lensed source. The standard solution to this paradox is based on the exact definition of the reference 'unlensed' situation. We calculate magnifications and amplifications for general lensing scenarios not limited to regions close to the optical axis. In this way the formalism is naturally extended from tangential planes for the source and lensed images to complete spheres. We derive the lensing potential theory on the sphere and find that the Poisson equation is modified by an additional source term that is related to the mean density and to the Newtonian potential at the positions of observer and source. This new term generally reduces the magnification, to below unity far from the optical axis, and ensures conservation of the total photon number received on a sphere around the source. This discussion does not affect the validity of the 'focusing theorem', in which the unlensed situation is defined to have an unchanged affine distance between source and observer. The focusing theorem does not contradict flux conservation, because the mean total magnification directly corresponds to different areas of the source sphere in the lensed and unlensed situation. We argue that a constant affine distance does not define an astronomically meaningful reference. By exchanging source and observer, we confirm that magnification and amplification differ according to Etherington's reciprocity law, so that surface brightness is no longer strictly conserved. [ abridged ]