Microvariability in BL Lacertae: “Zooming” into the Innermost Blazar Regions

Bhatta, Gopal; Webb, J. R.

doi:10.3390/galaxies6010002

Cited by 27 publications

(25 citation statements)

References 60 publications

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“…In the figure, it can be clearly seen that, not only does the source display long-term variability, but it also shows periodic flux modulation, such that, in each cycle, the flux nearly doubles between minimum and maximum. To quantify the observed long-term variability, we estimated a fractional variability [30,31] Figure 1. ∼10.5-year-long 15 GHz observations of blazar J1043+2408 from OVRO.…”

Section: Analysis and Resultsmentioning

confidence: 99%

“…To further confirm the presence of the above periodic timescale using a different method, we performed discrete correlation function analysis as described in Reference [40]. The method has been mostly applied to investigate cross-correlation between two time series with uneven spacing (see References [10][11][12]31]). With only one light curve, the method becomes a discrete autocorrelation function (ACF), which can be exploited to reveal the periodic signals in a light curve.…”

Section: Discrete Auto-cross-correlation Functionmentioning

confidence: 99%

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Detection of Periodic Radio Signal from the Blazar J1043+2408

Bhatta

2018

Galaxies

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The search for periodic signals from blazars has become a widely discussed topic in recent years. In the scenario that such periodic changes originate from the innermost regions of blazars, the signals bear imprints of the processes occurring near the central engine, which are mostly inaccessible to our direct view. Such signals provide insights into various aspect of blazar studies, including disk-jet connection, magnetic-field configuration and, more importantly, strong gravity near the supermassive black holes and release of gravitational waves from binary supermassive-black-hole systems. In this work, we report the detection of a periodic signal in the radio light curve of blazar J1043+2408 spanning ∼10.5 years. We performed multiple methods of time-series analysis, namely, epoch folding, Lomb–Scargle periodogram, and discrete autocorrelation function. All three methods consistently revealed a repeating signal with a periodicity of ∼560 days. To robustly account for the red-noise processes usually dominant in the blazar variability and other possible artefacts, a large number of Monte Carlo simulations were performed. This allowed us to estimate high significance (99.9% local and 99.4% global) against possible spurious detection. As possible explanations, we discuss a number of scenarios, including binary supermassive-black-hole systems, Lense–Thirring precession, and jet precession.

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Section: Analysis and Resultsmentioning

confidence: 99%

Section: Discrete Auto-cross-correlation Functionmentioning

confidence: 99%

Detection of Periodic Radio Signal from the Blazar J1043+2408

Bhatta

2018

Galaxies

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“…The discrete cross-correlation function (DCF) is one of the widely used methods to estimate cross correlations between unevenly sampled light curves of astrophysical sources (Edelson & Krolik 1988; see also Bhatta & Webb 2018). In the case of 4C +74.26, we evaluated the DCFs between the optical and the radio, the X-ray and the optical, and the X-ray and the radio flux changes.…”

Section: Discrete Correlation Functionmentioning

confidence: 99%

Signatures of the Disk–Jet Coupling in the Broad-line Radio Quasar 4C+74.26

Bhatta

Stawarz

Markowitz

et al. 2018

ApJ

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Here we explore the disk-jet connection in the broad-line radio quasar 4C+74.26, utilizing the results of the multiwavelength monitoring of the source. The target is unique in that its radiative output at radio wavelengths is dominated by a moderately-beamed nuclear jet, at optical frequencies by the accretion disk, and in the hard X-ray range by the disk corona. Our analysis reveals a correlation (local and global significance of 96% and 98%, respectively) between the optical and radio bands, with the disk lagging behind the jet by 250 ± 42 days. We discuss the possible explanation for this, speculating that the observed disk and the jet flux changes are generated by magnetic fluctuations originating within the innermost parts of a truncated disk, and that the lag is related to a delayed radiative response of the disk when compared with the propagation timescale of magnetic perturbations along relativistic outflow. This scenario is supported by the re-analysis of the NuSTAR data, modelled in terms of a relativistic reflection from the disk illuminated by the coronal emission, which returns the inner disk radius R in /R ISCO = 35 +40 −16 . We discuss the global energetics in the system, arguing that while the accretion proceeds at the Eddington rate, with the accretion-related bolometric luminosity L bol ∼ 9 × 10 46 erg s −1 ∼ 0.2L Edd , the jet total kinetic energy L j ∼ 4 × 10 44 erg s −1 , inferred from the dynamical modelling of the giant radio lobes in the source, constitutes only a small fraction of the available accretion power.

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“…Indeed, this object has become the prototype for an entire class of AGN, so understanding its behavior is very important. Multiband microvariability observations have been made by others [8,13]. Indeed, it has been observed in particular by Bhatta and Webb [13] that when brighter, BL Lac becomes bluer, and furthermore that emission is highly correlated across the various optical bands.…”

Section: Discussionmentioning

confidence: 88%

“…Multiband microvariability observations have been made by others [8,13]. Indeed, it has been observed in particular by Bhatta and Webb [13] that when brighter, BL Lac becomes bluer, and furthermore that emission is highly correlated across the various optical bands. Our observations were made in only one filter, R, but from previous work [13], we may assume that our documented outbursts were also well represented at other wavelengths.…”

Section: Discussionmentioning

confidence: 88%

The Microvariable Activity of BL Lacertae

et al. 2020

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We report on seven nights of optical observation taken over a two-week period, and the resultant analysis of the intermediate-frequency peaked BL Lac object (IBL), BL Lac itself, at redshift z = 0.069. The microvariable behavior can be confirmed over the course of minutes for each night. A relativistic beaming model was used in our analysis, to infer changes to the line of sight angles for the motion of the different relativistic components. This model has very few free parameters. The light curves we generated show both high and moderate frequency cadence to the variable behavior of BL Lac itself, in addition to the well documented long-term variability.

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Microvariability in BL Lacertae: “Zooming” into the Innermost Blazar Regions

Cited by 27 publications

References 60 publications

Detection of Periodic Radio Signal from the Blazar J1043+2408

Detection of Periodic Radio Signal from the Blazar J1043+2408

Signatures of the Disk–Jet Coupling in the Broad-line Radio Quasar 4C+74.26

The Microvariable Activity of BL Lacertae

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