Theory of optical long-baseline interferometry on polarized sources

TL;DR

This paper develops a comprehensive theory for optical long-baseline interferometry that accounts for polarization effects, enabling more accurate measurements of polarized astronomical sources with advanced interferometers.

Contribution

It introduces a generalized Mueller matrix formalism for multi-aperture interferometers, linking observed and source Stokes visibilities while addressing polarization crosstalk effects.

Findings

Derived a matrix relationship between observed and source Stokes visibilities.

Showed that classical visibilities must be debiased from polarization crosstalk.

Applied the formalism to single-mode interferometers.

Abstract

The effects of the polarization characteristics of beam trains in optical long-baseline interferometers are well known and have led to difficulties in measuring the spatial coherence of astronomical sources in the past. This has been overcome by designing symmetrical optical trains. With the advent of interferometers using large telescopes, observations of faint sources with high degrees of polarization have become even more possible. As in the radio domain, where radiation processes usually lead to high polarization rates, a description of coherence for polarized or unpolarized sources observed with non-polarization neutral interferometers is necessary. A theory of optical long-baseline interferometry fully taking into account the polarization characteristics of beam trains and those of the sources is presented in this paper, building on concepts developed for radio aperture synthesis. The concept of generalized Mueller matrix is introduced for the case of multi-aperture interferometers leading to a simple matrix relationship between the observed Stokes visibilities, as they are disturbed by the instrument polarization characteristics, and the object Stokes visibilities. This relationship is applied to the case of single-mode interferometers. The formalism also shows that classical complex visibilities (squared moduli, phases and closure phases) need to be debiased from polarization crosstalk, even when the source is not polarized as in this case ghost polarized visibilities are created.