Faraday Complexity and Depolarisation in a High-Rotation-Measure Radio Galaxy from the Spectra and Polarisation In Cutouts of Extragalactic Sources (SPICE-RACS) DR2

Abstract

We present a broadband spectro-polarimetric analysis of the extragalactic radio source RACS\0900-28\7036 using SPICE-RACS DR2 observations with the Australian Square Kilometre Array Pathfinder (ASKAP). The source was selected for its large rotation measure ( RM=345.70.2~ rad~m-2), substantial excess relative to the local foreground (Δ RM≈171~ rad~m-2), and strong evidence of Faraday complexity (σ add/δσ add≈8.6). Observations span 803--1083~MHz in 36 spectral channels, enabling detailed characterization of Faraday rotation and wavelength-dependent depolarization. One-dimensional q-u fitting and Bayesian model selection identify a multi-component model comprising one Burn-slab component and two external Faraday dispersion components (1 Slab + 2 EFD) as the preferred description. The dominant astrophysical component exhibits RM≈345.5~ rad~m-2 with modest Faraday dispersion (σ RM≈3~ rad~m-2), while a secondary broader component at RM≈131.5~ rad~m-2 shows strong depolarization (σ RM≈19.5~ rad~m-2). The fractional polarization spectrum and q--u plane evolution further confirm multiple Faraday-active regions along the line of sight. These results demonstrate that ASKAP broadband spectropolarimetry can resolve complex Faraday structures and probe turbulent magnetized environments, providing a framework for systematic depolarization studies across the full SPICE-RACS catalog and enabling statistical investigations of Faraday complexity in diverse extragalactic radio sources.