Modeling the Time Variability of SDSS Stripe 82 Quasars as a Damped Random Walk

MacLeod, Chelsea L.; Ivezić, Željko; Kochanek, C. S.; Kozłowski, S.; Kelly, Brandon C.; Bullock, E.; Kimball, Amy; Sesar, Branimir; Westman, David; Brooks, Keira; Gibson, R. R.; Becker, A. C.; Vries, W. H. de

doi:10.1088/0004-637x/721/2/1014

Cited by 625 publications

(993 citation statements)

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“…spectroscopic, color selection, UV excess) displaying significant optical variability when observed over several years (Schmidt et al 2010). The optical/IR flux changes occur 386 Vicki L. Sarajedini on timescales of months to years and have been well fit with damped random walk models indicating a characteristic timescale for variability and maximum amplitude at long time intervals (MacLeod et al 2010). Variability in AGN is likely due to instabilities in the accretion disk (e.g.…”

Section: Introductionmentioning

confidence: 93%

“…Variability in AGN is likely due to instabilities in the accretion disk (e.g. Li & Cao 2008) and has been found to correlate with several AGN parameters such as bolometric luminosity, wavelength and black hole mass (MacLeod et al 2010;Zuo et al 2012). In addition, intrinsically fainter AGN are found to have a higher amplitude of variability (Trevese et al 1994;Wilhite et al 2008) making variability selection particularly well-suited for identifying faint AGN.…”

Section: Introductionmentioning

confidence: 99%

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Using AGN Variability Surveys to explore the AGN-Galaxy Connection

Sarajedini¹

2013

Proc. IAU

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Abstract. Variability is a successful technique used to identify active galactic nuclei in both ground and space-based galaxy surveys. Optical variability surveys using HST have uncovered a number of AGN in deep extragalactic fields extending to z ∼ 3 and probing intrinsically faint sources. Mid-IR variability surveys using Spitzer have identified a significant number of AGN and are particularly sensitive to obscured sources. Many variability-detected AGN are not strong X-ray sources or lack the characteristic colors of AGN and would thus be unidentified using other selection techniques. In this conference proceedings, I discuss the nature of the variable sources and their host galaxies identified in deep extragalactic optical and mid-IR surveys.

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Section: Introductionmentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Using AGN Variability Surveys to explore the AGN-Galaxy Connection

Sarajedini¹

2013

Proc. IAU

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“…A sample of 9254 variable quasars is obtained from cross-matching the spectroscopic confirmed SDSS DR7 quasars (Schneider et al 2010;Shen et al 2011) and a sample of 67507 variable sources in SDSS Stripe 82, which lies along the celestial equator in the Southern Galactic Hemisphere (22h 24m < α J2000 < 04h 08m, −1.27 • < δ J2000 < +1.27 • , ∼ 290 deg 2 ) and have repeated photometric observations (at least 4 per band, with a median of 10) measured in up to 10 years in the u ′ g ′ r ′ i ′ z ′ system (Fukugita et al 1996;MacLeod et al 2010;Ivezić et al 2007;Sesar et al 2007). Black hole masses, bolometric luminosities and Eddington ratios are obtained from the quasar catalog in Shen et al (2011), where the black hole masses of quasars were settled by fiducial virial mass estimates: Hβ (Vestergaard & Wilkes 2006) estimates for z < 0.7, [MgII] (Shen & Kelly 2010) estimates for 0.7 ≤ z < 1.9 and CIV] (Vestergaard & Wilkes 2006) estimates for z ≥ 1.9.…”

Section: Samplementioning

confidence: 99%

The correlations between optical variability and physical parameters of quasars in SDSS Stripe 82

Zuo¹,

Wu²,

Liu³

et al. 2012

Proc. IAU

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We investigate the optical variability of 7658 quasars from SDSS Stripe 82. Taking advantage of a larger sample and relatively more data points for each quasar, we estimate variability amplitudes and divide the sample into small bins of redshift, rest-frame wavelength, black hole mass, Eddington ratio and bolometric luminosity respectively, to investigate the relationships between variability and these parameters. An anti-correlation between variability and rest-frame wavelength is found. The variability amplitude of radio-quiet quasars shows almost no cosmological evolution, but that of radio-loud ones may weakly anticorrelate with redshift. In addition, variability increases as either luminosity or Eddington ratio decreases. However, the relationship between variability and black hole mass is uncertain; it is negative when the influence of Eddington ratio is excluded, but positive when the influence of luminosity is excluded. The intrinsic distribution of variability amplitudes for radio-loud and radio-quiet quasars are different. Both radio-loud and radio-quiet quasars exhibit a bluer-whenbrighter chromatism. Assuming that quasar variability is caused by variations of accretion rate, the Shakura-Sunyaev disk model can reproduce the tendencies of observed correlations between variability and rest-frame wavelength, luminosity as well as Eddington ratio, supporting that changes of accretion rate plays an important role in producing the observed optical variability. However, the predicted positive correlation between variability and black hole mass seems to be inconsistent with the observed negative correlation between them in small bins of Eddington ratio, which suggests that other physical mechanisms may still need to be considered in modifying the simple accretion disk model.

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“…The damped random walk (DRW) model is an increasingly successful method of quantifying the variability of active galactic nuclei (AGNs; Kelly et al 2009;Koz lowski et al 2010;MacLeod et al 2010;Zu et al 2011Zu et al , 2013. Kelly et al (2009) introduce DRW as an underlying stochastic process leading to AGN variability, also known as the continuous-time first order autoregressive process [CAR(1)] or Ornstein-Uhlenbeck process (Uhlenbeck & Ornstein 1930).…”

Section: Introductionmentioning

confidence: 99%

“…Kelly et al (2009) introduce DRW as an underlying stochastic process leading to AGN variability, also known as the continuous-time first order autoregressive process [CAR(1)] or Ornstein-Uhlenbeck process (Uhlenbeck & Ornstein 1930). The model has two parameters, the time-scale τ after which the light curve becomes uncorrelated and the modified amplitudeσ (Koz lowski et al 2010) or asymptotic amplitude SF∞ (MacLeod et al 2010). These two parameters show correlations with the physical parameters of AGNs, such as the black hole mass, luminosity, Eddington ratio, and rest-frame wavelength.…”

Section: Introductionmentioning

confidence: 99%

A degeneracy in DRW modelling of AGN light curves

Kozłowski

2016

Mon. Not. R. Astron. Soc.

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Individual light curves of active galactic nuclei (AGNs) are nowadays successfully modelled with the damped random walk (DRW) stochastic process, characterized by the power exponential covariance matrix of the signal, with the power β = 1. By Monte Carlo simulation means, we generate mock AGN light curves described by non-DRW stochastic processes (0.5 ≤ β ≤ 1.5 and β = 1) and show they can be successfully and well modelled as a single DRW process, obtaining comparable goodness of fits. A good DRW fit, in fact, may not mean that DRW is the true underlying process leading to variability and it cannot be used as a proof for it. When comparing the input (non-DRW) and measured (DRW) process parameters, the recovered time-scale (amplitude) increases (decreases) with the increasing input β. In practice, this means that the recovered DRW parameters may lead to biased (or even non-existing) correlations of the variability and physical parameters of AGNs if the true AGN variability is caused by non-DRW stochastic processes. The proper way of identifying the processes leading to variability are model-independent structure functions and/or power spectral densities and then using such information on the covariance matrix of the signal in light curve modelling.

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Modeling the Time Variability of SDSS Stripe 82 Quasars as a Damped Random Walk

Cited by 625 publications

References 81 publications

Using AGN Variability Surveys to explore the AGN-Galaxy Connection

Using AGN Variability Surveys to explore the AGN-Galaxy Connection

The correlations between optical variability and physical parameters of quasars in SDSS Stripe 82

A degeneracy in DRW modelling of AGN light curves

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