X-ray spectroscopy of active galactic nuclei (AGNs) offers unique insights into the reprocessing of radiation and the gas dynamics near supermassive black holes. The Seyfert 1 galaxy Mrk 509 is an ideal laboratory for these studies. It is in fact known for its complex iron K emission and one of the four or five AGNs to date in which evidence of transient, blue- and redshifted absorption features indicative of high-velocity flows has been detected in X-rays. We present the first high-resolution 2--10, keV spectrum of Mrk 509 obtained with the XRISM /Resolve calorimeter. Our primary goals are to disentangle the narrow and broad emission features and to place stringent constraints on the kinematics and physical locations of circumnuclear gas flows, specifically searching for signatures of accretion and feedback. We analyzed 106 ks of XRISM/Resolve data, complemented by simultaneous and observations, which we used to constrain the broadband continuum. We modeled the spectra using self-consistent reflection models for the continuum and the emission lines, and employed photoionized plasma models to characterize discrete, ionized absorption features. XMM-Newton NuSTAR The XRISM/Resolve spectrum reveals a narrow Fe Kα core resolved with σ ∼ 1100 km/s). The best-fit model includes a broader component with σ (v_ FWHM We also find tentative evidence of discrete absorption features at rest-frame energies of E, located within the inner few thousand gravitational radii. When modeled as an ionized absorber (with a significance of sim3. 6σ), the data suggest the gas is redshifted relative to the systemic velocity, corresponding to an inflow of material with v_ ̊m in -1 The narrow Fe Kα emission is consistent with an origin in the dusty torus, while the broad component arises from broad-line-region scales or the accretion disk (R This scenario is strongly corroborated by our relativistic reflection modeling, which restricts the inner edge of the emitting region to distances greater than 27, rg. If confirmed by future observations, the high-velocity inflow would likely represent dense, fragmented clumps of a ``failed wind'' raining back onto the accretion disk, providing potential direct evidence that nonstandard accretion processes may coexist with canonical disk-like flows in the inner regions of AGNs.
Dadina et al. (Thu,) studied this question.