Strong lensing cross sections for isothermal models - I. Finite source effects in the circular case

TL;DR

This paper derives analytical formulas for gravitational lensing cross sections considering finite source sizes, focusing on circular models, which improve understanding and computational efficiency in galaxy-galaxy lensing studies.

Contribution

It provides the first closed-form analytical solutions for lensing cross sections with finite sources in the circular case, enhancing modeling accuracy and computational speed.

Findings

Derived exact magnification cross section formulas.

Presented simple approximations for arc and Einstein ring regimes.

Quantified finite source corrections with perturbative expansions.

Abstract

The strong galaxy-galaxy lensing produces highly magnified and distorted images of background galaxies in the form of arcs and Einstein rings. Statistically, these effects are quantified, for example, in the number counts of highly luminous sub-millimeter galaxies and of gravitational arcs. Two key quantities to model these statistics are the magnification and the arc cross sections. These are usually computed using either the circular infinitesimal source approximation or ray-tracing simulations for sources of finite size. In this work, we use an analytic solution for gravitational arcs to obtain these cross sections as a function of image magnification and length-to-width ratio in closed form, for finite sources. These analytical solutions provide simple interpretations to the numerical results, can be employed to test the computational codes, and can be used for fast a computation of the abundance of distant sources and arcs. In this paper, the lens is modeled by a Singular Isothermal Sphere, which is an excellent approximation to radial density profile of Early-Type galaxies, and the sources are also axisymmetric. We derive expressions for the geometrical properties of the images, such as the area and several definitions of length and width. We obtain the magnification cross section in exact form and derive a simple analytic approximation covering the arc and Einstein ring regimes. The arc cross section is obtained down to the formation of an Einstein ring and given in terms of elementary functions. Perturbative expansions of these results are worked out, showing explicitly the correction terms for finite sources.