Recent X-ray observations show absorbing winds with velocities up to mildly relativistic values of the order of ~0.1c in a limited sample of six broad-line radio galaxies. They are observed as blueshifted Fe XXV-XXVI K-shell absorption lines, similarly to the ultrafast outflows (UFOs) reported in Seyferts and quasars. In this work we extend the search for such Fe K absorption lines to a larger sample of 26 radio-loud active galactic nuclei (AGN) observed with XMM-Newton and Suzaku. The sample is drawn from the Swift Burst Alert Telescope 58-month catalogue and blazars are excluded. X-ray bright Fanaroff-Riley Class II radio galaxies constitute the majority of the sources. Combining the results of this analysis with those in the literature we find that UFOs are detected in >27 per cent of the sources. However, correcting for the number of spectra with insufficient signal-to-noise ratio, we can estimate that the incidence of UFOs is this sample of radio-loud AGN is likely in the range f ≃ (50 ± 20) per cent. A photoionization modelling of the absorption lines with XSTAR allows us to estimate the distribution of their main parameters. The observed outflow velocities are broadly distributed between vout ≲ 1000km s-1 and νout ≃ 0.4c, with mean and median values of νout ≃ 0.133c and vout ≃ 0.117c, respectively. The material is highly ionized, with an average ionization parameter of logξ ≃ 4.5 erg s-1cm, and the column densities are larger than NH > 1022cm-2. Overall, these characteristics are consistent with the presence of complex accretion disc winds in a significant fraction of radio-loud AGN and demonstrate that the presence of relativistic jets does not preclude the existence of winds, in accordance with several theoretical models. © 2014 The Authors. Published by Oxford University Press on behalf of the Royal Astronomical Society.
CITATION STYLE
Tombesi, F., Tazaki, F., Mushotzky, R. F., Ueda, Y., Cappi, M., Gofford, J., … Guainazzi, M. (2014). Ultrafast outflows in radio-loud active galactic nuclei. Monthly Notices of the Royal Astronomical Society, 443(3), 2154–2182. https://doi.org/10.1093/mnras/stu1297
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