Location and energetics of the ultra-fast outflow in PG 1448+273

Abstract

Ultra-fast outflows (UFOs) play a key role in the AGN feedback mechanism. It is therefore important to fully characterize their location and energetics. We study the UFO in the latest XMM-Newton archival observation of the NLSy1 galaxy PG 1448+273 by means of a novel modeling tool, that is, the Wind in the Ionized Nuclear Environment model (WINE). Our detection of the UFO in PG 1448+273 is very robust. The outflowing material is highly ionized, = 5.53-0.05+0.04 erg s-1 cm, has a large column density, NH = 4.5-1.1+0.8 × 1023 cm-2, is ejected with a maximum velocity v0 = 0.24+0.08-0.06\,c (90% c.l. errors), and attains an average velocity vavg = 0.152\,c. WINE succeeds remarkably well to constrain a launching radius of r0=77-19+31 \, rS from the black hole. We also derive a lower limit on both the opening angle of the wind (θ > 72) and the covering factor (Cf > 0.69). We find a mass outflow rate Mout=0.65+0.44-0.33\,M yr-1 = 2.0+1.3-1.0\, Macc and a large instantaneous outflow kinetic power Eout=4.4+4.4-3.6 × 1044 erg s-1 = 24% Lbol = 18% LEdd (1 σ errors). We find that a major error contribution on the energetics is due to r0, stressing the importance of an accurate determination through a proper spectral modeling, as done with WINE. Using 20 Swift (UVOT and XRT) observations and the simultaneous OM data from XMM-Newton, we also find that αox undergoes large variations, with a maximum excursion of αox =-0.7, after the UFO is detected, leading to a remarkable X-ray weakness. This may point towards a starving of the inner accretion disk due to the removal of matter through the wind.