A note on periodicity of long-term variations of optical continuum in active galactic nuclei

Graham et al. found a sample of active galactic nuclei (AGNs) and quasars from the Catalina Real-time Transient Survey (CRTS) that have long-term periodic variations in optical continuum, the nature of the periodicity remains uncertain. We investigate the periodic variability characteristics of the sample by testing the relations of the observed variability periods with AGN optical luminosity, black hole mass and accretion rates, and find no significant correlations. We also test the observed periods in several different aspects related to accretion disks surrounding single black holes, such as the Keplerian rotational periods of 5100~\AA\ photon-emission regions and self-gravity dominated regions and the precessing period of warped disks. These tests shed new lights on understanding AGN variability in general. Under the assumption that the periodic behavior is associated with SMBHB systems in particular, we compare the separations ($\mathscr{D}_{\bullet}$) against characteristic radii of broad-line regions ($R_{\rm BLR}$) of the binaries and find $\mathscr{D}_{\bullet}$$\approx$ 0.05 $R_{\rm BLR}$. This interestingly implies that these binaries have only circumbinary BLRs.

[1]  L. Ho,et al.  SPECTROSCOPIC INDICATION OF A CENTI-PARSEC SUPERMASSIVE BLACK HOLE BINARY IN THE GALACTIC CENTER OF NGC 5548 , 2016, 1602.05005.

[2]  D. Schiminovich,et al.  Relativistic boost as the cause of periodicity in a massive black-hole binary candidate , 2015, Nature.

[3]  Youjun Lu,et al.  A PROBABLE MILLI-PARSEC SUPERMASSIVE BINARY BLACK HOLE IN THE NEAREST QUASAR MRK 231 , 2015, 1508.06292.

[4]  Ciro Donalek,et al.  A systematic search for close supermassive black hole binaries in the Catalina Real-time Transient Survey , 2015, 1507.07603.

[5]  S. Gezari,et al.  A PERIODICALLY VARYING LUMINOUS QUASAR AT z = 2 FROM THE PAN-STARRS1 MEDIUM DEEP SURVEY: A CANDIDATE SUPERMASSIVE BLACK HOLE BINARY IN THE GRAVITATIONAL WAVE-DRIVEN REGIME , 2015, Proceedings of the International Astronomical Union.

[6]  S. Djorgovski,et al.  A possible close supermassive black-hole binary in a quasar with optical periodicity , 2015, Nature.

[7]  C. A. Oxborrow,et al.  Planck 2013 results. XXXI. Consistency of the Planck data , 2014, 1508.03375.

[8]  Astrophysics,et al.  THE BLACK HOLE MASS SCALE OF CLASSICAL AND PSEUDO BULGES IN ACTIVE GALAXIES , 2014, 1406.6137.

[9]  S. Komossa,et al.  A MILLIPARSEC SUPERMASSIVE BLACK HOLE BINARY CANDIDATE IN THE GALAXY SDSS J120136.02+300305.5 , 2014, 1404.4933.

[10]  Fang Wang,et al.  SUPERMASSIVE BLACK HOLES WITH HIGH ACCRETION RATES IN ACTIVE GALACTIC NUCLEI. I. FIRST RESULTS FROM A NEW REVERBERATION MAPPING CAMPAIGN , 2013, 1310.4107.

[11]  P. Duffell,et al.  BINARY BLACK HOLE ACCRETION FROM A CIRCUMBINARY DISK: GAS DYNAMICS INSIDE THE CENTRAL CAVITY , 2013, 1310.0492.

[12]  Liming Song,et al.  A statistical study on the low-frequency quasi-periodic oscillation amplitude spectrum and amplitude in GRS 1915+105 , 2013, 1306.0640.

[13]  Bradley M. Peterson,et al.  THE LOW-LUMINOSITY END OF THE RADIUS–LUMINOSITY RELATIONSHIP FOR ACTIVE GALACTIC NUCLEI , 2013, 1303.1742.

[14]  T. Boroson,et al.  A LARGE SYSTEMATIC SEARCH FOR CLOSE SUPERMASSIVE BINARY AND RAPIDLY RECOILING BLACK HOLES , 2012, 1509.02575.

[15]  Yue Shen,et al.  IDENTIFYING SUPERMASSIVE BLACK HOLE BINARIES WITH BROAD EMISSION LINE DIAGNOSIS , 2009, 0912.0541.

[16]  Ling Zhu,et al.  CALIBRATING THE CORRELATION BETWEEN BLACK HOLE MASS AND X-RAY VARIABILITY AMPLITUDE: X-RAY ONLY BLACK HOLE MASS ESTIMATES FOR ACTIVE GALACTIC NUCLEI AND ULTRA-LUMINOUS X-RAY SOURCES , 2009, 0912.2636.

[17]  O. Gerhard,et al.  Self-gravitating warped discs around supermassive black holes , 2009, 0909.5333.

[18]  L. Ho,et al.  A Systematic Analysis of Fe II Emission in Quasars: Evidence for Inflow to the Central Black Hole , 2008, 0807.2059.

[19]  M. Kidger,et al.  A massive binary black-hole system in OJ 287 and a test of general relativity , 2008, Nature.

[20]  G. Richards,et al.  Biases in Virial Black Hole Masses: An SDSS Perspective , 2007, 0709.3098.

[21]  B. Peterson,et al.  Determining Central Black Hole Masses in Distant Active Galaxies and Quasars. II. Improved Optical and UV Scaling Relationships , 2002, astro-ph/0601303.

[22]  W. Kluźniak,et al.  A precise determination of black hole spin in GRO J1655-40 , 2001 .

[23]  M. Kamionkowski,et al.  Weak Lensing by Large-Scale Structure with The FIRST Radio Survey , 1998, astro-ph/9810025.

[24]  B. Czerny,et al.  Observational constraints on viscosity in AGN accretion discs , 1989 .

[25]  C. Clarke,et al.  Thermal light variations of active galactic nuclei , 1989 .

[26]  William H. Press,et al.  Book-Review - Numerical Recipes in Pascal - the Art of Scientific Computing , 1989 .

[27]  Donald E. Osterbrock,et al.  Emission-line regions of active galaxies and QSOs , 1986 .

[28]  M. Rees BLACK HOLE MODELS FOR ACTIVE GALACTIC NUCLEI , 1984 .

[29]  M. Rees,et al.  Massive black hole binaries in active galactic nuclei , 1980, Nature.

[30]  Maurice G. Kendall,et al.  The Advanced Theory of Statistics, Vol. 2: Inference and Relationship , 1979 .