Walton, D. J.D. J.WaltonAlston, W. N.W. N.AlstonKosec, P.P.KosecFabian, A. C.A. C.FabianGallo, L. C.L. C.GalloGarcia, J. A.J. A.GarciaMiller, J. M.J. M.MillerNARDINI, EmanueleEmanueleNARDINIReynolds, M. T.M. T.ReynoldsRicci, C.C.RicciStern, D.D.SternDauser, T.T.DauserHarrison, F. A.F. A.HarrisonReynolds, C. S.C. S.Reynolds2024-12-232024-12-2320200035-8711http://hdl.handle.net/20.500.12386/35561We present new broad-band X-ray observations of the type-I Seyfert galaxy IRAS 09149-6206, taken in 2018 with XMM-Newton, NuSTAR, and Swift. The source is highly complex, showing a classic 'warm' X-ray absorber, additional absorption from highly ionized iron, strong relativistic reflection from the innermost accretion disc and further reprocessing by more distant material. By combining X-ray timing and spectroscopy, we have been able to fully characterize the supermassive black hole in this system, constraining both its mass and - for the first time - its spin. The mass is primarily determined by X-ray timing constraints on the break frequency seen in the power spectrum, and is found to be log [M<SUB>BH</SUB>/M<SUB>⊙</SUB>] = 8.0 ± 0.6 (1σ uncertainties). This is in good agreement with previous estimates based on the H α and H β line widths, and implies that IRAS 09149-6206 is radiating at close to (but still below) its Eddington luminosity. The spin is constrained via detailed modelling of the relativistic reflection, and is found to be $a^* = 0.94^{+0.02}_{-0.07}$ (90 per cent confidence), adding IRAS 09149-6206 to the growing list of radio-quiet active galactic nuclei (AGNs) that host rapidly rotating black holes. The outflow velocities of the various absorption components are all relatively modest (v<SUB>out</SUB> ≲ 0.03c), implying these are unlikely to drive significant galaxy-scale AGN feedback.STAMPAenArticle10.1093/mnras/staa29612-s2.0-85098574177https://academic.oup.com/mnras/article/499/1/1480/5917086http://arxiv.org/abs/2009.10734v12020MNRAS.499.1480WFIS/05 - ASTRONOMIA E ASTROFISICA