Polarized radiative transfer modeling of warped and clumpy dusty tori

TL;DR

This study uses polarized radiative transfer simulations to investigate how warped and clumpy dusty tori in active galactic nuclei affect polarization signatures, aiding in understanding their true geometry and testing unified models.

Contribution

It introduces detailed modeling of warped and clumpy dusty tori and assesses their polarization signatures within AGN, providing new insights into their detectability and geometry.

Findings

Warped structures produce distinctive polarization signatures at Seyfert-1 orientations.

Multiple scattering in clumpy environments can obscure warp signatures.

Imaging polarimetry can help detect warped tori in AGN.

Abstract

Context: Active galactic nuclei (AGN) are anisotropic objects surrounded by an optically thick equatorial medium whose true geometry still defy observers. Aims: In this paper, we aim to explore the optical, scattering-induced, polarization emerging from clumpy and warped dusty tori to check whether they can fit with the unified model predictions. Methods: We run polarized radiative transfer simulations in a set of warped and non warped clumpy tori to explore the differences induced by distorted dust distributions. We then include warped tori in a more complex model representative of an AGN to check, using polarimetry and imaging methods, if warps can reproduce the expected polarization dichotomy between Seyfert-1 and Seyfert-2 AGN. Results: The main results from our simulations highlight that isolated warped structures imprint the polarization degree and angle with distinctive signatures at Seyfert-1 orientations. Included in an AGN model, the signatures of warps are easily (but not always) washed out by multiple scattering in a clumpy environment. Imaging polarimetry may help to detect warped tori but we prove that warps can exist in AGN circumnuclear regions without contradicting observations. Conclusions: Two warped tori with a non significant difference in geometry in terms of photometry or spectroscopy can have totally different signatures in polarimetry. Testing the geometry of any alternative model to the usual dusty torus using polarized radiative transfer is a necessary approach to verify or reject a hypothesis.