Space Telescope and Optical Reverberation Mapping Project. XIII. An Atlas of UV and X-Ray Spectroscopic Signatures of the Disk Wind in NGC 5548

The unusual behavior of the spectral lines of NGC5548 during the STORM campaign demonstrated a missing piece in the structure of AGNs. For a two-month period in the middle of the campaign, the spectral lines showed a deficit in flux and a reduced response to the variations of the UV continuum. This was the first time that this behavior was unequivocally observed in an AGN. Our previous papers explained this as being due to a variable disk wind that acts as a shield and alters the SED. Here, we use Cloudy to create an atlas of photoionization models for a variety of disk winds, in order to study their effects on the SED. We show that the winds have three different cases: Case 1 winds are transparent, fully ionized, and have minimal effects on the intrinsic SED, although they can produce some line emission, especially He ii or FeKα. We propose that this is the situation in most of the AGNs. Case 2 winds, which have a He++–He+ ionization front, block part of the XUV continuum but transmit much of the Lyman continuum. They lead to the observed abnormal behavior. Case 3 winds have a H+ ionization front and block much of the Lyman continuum. The results show that the presence of these winds has important effects on the spectral lines of AGNs. They will thus have an effect on the measurements of the black hole mass and the geometry of the AGN. This atlas of spectral simulations can serve as a guide to future reverberation campaigns.

[1]  D. N. Okhmat,et al.  Space Telescope and Optical Reverberation Mapping Project. IX. Velocity–Delay Maps for Broad Emission Lines in NGC 5548 , 2020, The Astrophysical Journal.

[2]  W. Brandt,et al.  Space Telescope and Optical Reverberation Mapping Project. XI. Disk-wind Characteristics and Contributions to the Very Broad Emission Lines of NGC 5548 , 2020, Astrophysical Journal.

[3]  F. Guzmán,et al.  A Wind-based Unification Model for NGC 5548: Spectral Holidays, Nondisk Emission, and Implications for Changing-look Quasars , 2019, The Astrophysical Journal.

[4]  K. Korista,et al.  Quantifying the impact of variable BLR diffuse continuum contributions on measured continuum interband delays , 2019, Monthly notices of the Royal Astronomical Society.

[5]  P. Hall,et al.  Space Telescope and Optical Reverberation Mapping Project. VIII. Time Variability of Emission and Absorption in NGC 5548 Based on Modeling the Ultraviolet Spectrum , 2019, The Astrophysical Journal.

[6]  W. Brandt,et al.  Space Telescope and Optical Reverberation Mapping Project. X. Understanding the Absorption-line Holiday in NGC 5548 , 2018, The Astrophysical Journal.

[7]  K. Korista,et al.  Quantifying the diffuse continuum contribution of BLR Clouds to AGN Continuum Inter-band Delays , 2018, Monthly Notices of the Royal Astronomical Society.

[8]  H. Schmitt,et al.  Quantifying Feedback from Narrow Line Region Outflows in Nearby Active Galaxies. I. Spatially Resolved Mass Outflow Rates for the Seyfert 2 Galaxy Markarian 573 , 2018, 1802.07734.

[9]  D. N. Okhmat,et al.  Space Telescope and Optical Reverberation Mapping Project. VII. Understanding the Ultraviolet Anomaly in NGC 5548 with X-Ray Spectroscopy , 2017, 1704.06345.

[10]  D. N. Okhmat,et al.  Space Telescope and Optical Reverberation Mapping Project. V. Optical Spectroscopic Campaign and Emission-line Analysis for NGC 5548 , 2017, 1702.01177.

[11]  D. N. Okhmat,et al.  SPACE TELESCOPE AND OPTICAL REVERBERATION MAPPING PROJECT.VI. REVERBERATING DISK MODELS FOR NGC 5548 , 2016, 1611.06051.

[12]  S. Paltani,et al.  Anatomy of the AGN in NGC 5548 VIII. XMM-Newton's EPIC detailed view of an unexpected variable multilayer absorber , 2016, 1604.01777.

[13]  D. N. Okhmat,et al.  SPACE TELESCOPE AND OPTICAL REVERBERATION MAPPING PROJECT. IV. ANOMALOUS BEHAVIOR OF THE BROAD ULTRAVIOLET EMISSION LINES IN NGC 5548 , 2016, 1603.08741.

[14]  S. Paltani,et al.  Anatomy of the AGN in NGC 5548: VII. Swift study of obscuration and broadband continuum variability , 2016, 1602.03017.

[15]  G. Kriss,et al.  Anatomy of the AGN in NGC 5548. VI. Long-term variability of the warm absorber , 2016, 1601.02385.

[16]  M. C. Bentz,et al.  SPACE TELESCOPE AND OPTICAL REVERBERATION MAPPING PROJECT. III. OPTICAL CONTINUUM EMISSION AND BROADBAND TIME DELAYS IN NGC 5548 , 2015, 1510.05648.

[17]  S. Paltani,et al.  Anatomy of the AGN in NGC 5548: V. A clear view of the X-ray narrow emission lines , 2015, 1509.00274.

[18]  S. Paltani,et al.  Anatomy of the AGN in NGC 5548 IV. The short-term variability of the outflows , 2015, 1505.02562.

[19]  O. Shemmer,et al.  WEAK EMISSION-LINE QUASARS IN THE CONTEXT OF A MODIFIED BALDWIN EFFECT , 2015, 1503.07547.

[20]  P. Hall,et al.  SPACE TELESCOPE AND OPTICAL REVERBERATION MAPPING PROJECT. I. ULTRAVIOLET OBSERVATIONS OF THE SEYFERT 1 GALAXY NGC 5548 WITH THE COSMIC ORIGINS SPECTROGRAPH ON HUBBLE SPACE TELESCOPE , 2015, 1501.05954.

[21]  M. C. Bentz,et al.  SPACE TELESCOPE AND OPTICAL REVERBERATION MAPPING PROJECT. II. SWIFT AND HST REVERBERATION MAPPING OF THE ACCRETION DISK OF NGC 5548 , 2015, 1501.05951.

[22]  S. Paltani,et al.  Anatomy of the AGN in NGC 5548 - III. The high-energy view with NuSTAR and INTEGRAL , 2015, 1501.03426.

[23]  S. Paltani,et al.  Anatomy of the AGN in NGC 5548 - I. A global model for the broadband spectral energy distribution , 2015, 1501.01188.

[24]  S. Paltani,et al.  Anatomy of the AGN in NGC 5548 - II. The spatial, temporal, and physical nature of the outflow from HST/COS Observations , 2014, 1411.2157.

[25]  S. Paltani,et al.  A fast and long-lived outflow from the supermassive black hole in NGC 5548 , 2014, Science.

[26]  G. Ferland,et al.  Intervening BLR Clouds' Effects on Optical/UV Spectrum , 2012, 1205.5817.

[27]  K. Leighly Hubble Space Telescope STIS Ultraviolet Spectral Evidence of Outflow in Extreme Narrow-Line Seyfert 1 Galaxies. II. Modeling and Interpretation , 2004, astro-ph/0402452.

[28]  Gary J. Ferland,et al.  Quantitative Spectroscopy of Photoionized Clouds , 2003 .

[29]  C. Reynolds,et al.  Fluorescent iron lines as a probe of astrophysical black hole systems , 2003 .

[30]  Yu. F. Malkov,et al.  Steps toward Determination of the Size and Structure of the Broad-Line Region in Active Galactic Nuclei. XVI. A 13 Year Study of Spectral Variability in NGC 5548 , 2002, astro-ph/0208064.

[31]  T. Kallman,et al.  Photoionization and High-Density Gas , 2013 .

[32]  K. Korista,et al.  The Variable Diffuse Continuum Emission of Broad-Line Clouds , 2001, astro-ph/0101117.

[33]  Kirk T. Korista,et al.  Locally Optimally Emitting Clouds and the Variable Broad Emission Line Spectrum of NGC 5548 , 2000, astro-ph/0001399.

[34]  D. Crenshaw,et al.  The Effect of Intrinsic Ultraviolet Absorbers on the Ionizing Continuum and Narrow Emission Line Ratios in Seyfert Galaxies , 1999, astro-ph/9902161.

[35]  J. Chiang,et al.  Accretion Disk Winds from Active Galactic Nuclei , 1995 .

[36]  Bradley M. Peterson,et al.  REVERBERATION MAPPING OF ACTIVE GALACTIC NUCLEI , 1993 .

[37]  G. Ferland,et al.  Broad Line Region Clouds and the Absorbing Material in NGC 4151 , 1982 .

[38]  Christopher F. McKee,et al.  Reverberation mapping of the emission line regions of Seyfert galaxies and quasars. , 1982 .