Catching the radio flare in CTA 102

Fromm, Christian M.; Ros, E.; Perucho, M.; Savolainen, Tuomas; Mimica, P.; Kadler, M.; Lobanov, A. P.; Zensus, J. A.

doi:10.1051/0004-6361/201321784

Cited by 104 publications

(126 citation statements)

References 25 publications

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“…An additional uncertainty in α of up to 15% is also to be expected, arising from the different uv-coverages (e.g. Fromm et al 2013). To obtain the same parameters during the highest state of the knot, the fit was performed once more only at epoch 2009.9.…”

Section: Spectra Of Individual Knotsmentioning

confidence: 99%

PKS 1502+106: A high-redshiftFermiblazar at extreme angular resolution

Karamanavis

Fuhrmann

Krichbaum

et al. 2016

A&A

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Context. Blazars are among the most energetic objects in the Universe. In 2008 August, Fermi/LAT detected the blazar PKS 1502+106, which showed a rapid and strong γ-ray outburst followed by high and variable flux over the next months. This activity at high energies triggered an intensive multi-wavelength campaign that also covered the radio, optical, UV, and X-ray bands, indicating that the flare was accompanied by a simultaneous outburst at optical/UV/X-rays and a delayed outburst at radio bands. Aims. We explore the phenomenology and physical conditions within the ultra-relativistic jet of the γ-ray blazar PKS 1502+106. Additionally, we address the question of the spatial localization of the MeV/GeV-emitting region of the source. Methods. We used ultra-high angular resolution mm-VLBI observations at 43 and 86 GHz complemented by VLBI observations at 15 GHz. We also employed single-dish radio data from the F-GAMMA program at frequencies matching the VLBI monitoring. Results. PKS 1502+106 shows a compact core-jet morphology and fast superluminal motion with apparent speeds in the range 5-22 c. Estimating Doppler factors along the jet yields values of between ∼7 up to ∼50. This Doppler factor gradient implies an accelerating jet. The viewing angle towards the source differs between the inner and outer jet, with the former at θ ∼ 3 • and the latter at θ ∼ 1 • , after the jet bends towards the observer beyond 1 mas. The de-projected opening angle of the ultra-fast magnetically dominated jet is found to be (3.8 ± 0.5) • . A single jet component can be associated with the pronounced flare both at high energies and in radio bands. Finally, the γ-ray emission region is localized at ≤5.9 pc away from the jet base.

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Section: Spectra Of Individual Knotsmentioning

confidence: 99%

PKS 1502+106: A high-redshiftFermiblazar at extreme angular resolution

Karamanavis

Fuhrmann

Krichbaum

et al. 2016

A&A

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“…This can be due to the passage of the C3 component through the core, which is modelled at 23.8-43.2 GHz separately, but blended with the core component at lower frequencies. But most probably, hardening of the spectra can be explained by particle injection (Fromm et al 2013) during the flare and energy losses (Marscher & Gear 1985). Emission downstream the core shows optically thin emission (see example in Fig.…”

Section: Evolution Of the Spectrummentioning

confidence: 99%

Multiwavelength observations of the γ-ray flaring quasar S4 1030+61 in 2009–2014

Kravchenko

Kovalev

Hovatta

2016

Mon. Not. R. Astron. Soc.

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We present a study of the parsec-scale multi-frequency properties of the quasar S4 1030+61 during a prolonged radio and γ-ray activity. Observations were performed within Fermi γ-ray telescope, OVRO 40-m telescope and MOJAVE VLBA monitoring programs, covering five years from 2009. The data are supplemented by four-epoch VLBA observations at 5, 8, 15, 24, and 43 GHz, which were triggered by the bright γ-ray flare, registered in the quasar in 2010. The S4 1030+61 jet exhibits an apparent superluminal velocity of (6.4±0.4)c and does not show ejections of new components in the observed period, while decomposition of the radio light curve reveals nine prominent flares. The measured variability parameters of the source show values typical for Fermi-detected quasars. Combined analysis of radio and γ-ray emission implies a spatial separation between emitting regions at these bands of about 12 pc and locates the γ-ray emission within a parsec from the central engine. We detected changes in the value and direction of the linear polarization and the Faraday rotation measure. The value of the intrinsic brightness temperature of the core is above the equipartition state, while its value as a function of distance from the core is well approximated by the power-law. Altogether these results show that the radio flaring activity of the quasar is accompanied by injection of relativistic particles and energy losses at the jet base, while S4 1030+61 has a stable, straight jet well described by standard conical jet theories.

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“…Due to the rough agreement of the magnetic field strength in the γ-ray emitting region and that of the radio core at the pc scale (e.g., Fromm et al 2013;Zamaninasab et al 2014;Agarwal et al 2017), we calculate the location of the γ-ray emitting region for these blazars by assuming that the magnetic field strength derived in the SED fitting follows the magnetic field strength distribution as derived from the radio core-shift measurements. The main results are summarized as follows.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

Constraints on the Location of γ-Ray Sample of Blazars with Radio Core-shift Measurements

Yan

et al. 2018

ApJ

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We model simultaneous or quasi-simultaneous multi-band spectral energy distributions (SEDs) for a sample of 25 blazars that have radio core-shift measurements, where a one-zone leptonic model and Markov chain Monte Carlo technique are adopted. In the SED fitting for 23 low-synchrotron-peaked (LSP) blazars, the seed photons from the broad-line (BLR) and molecular torus are considered respectively in the external Compton process. We find that the SED fitting with the seed photons from the torus are better than those utilizing BLR photons, which suggest that the γ-ray emitting region may be located outside the BLR. Assuming the magnetic field strength in the γ-ray emitting region as constrained from the SED fitting follows the magnetic field distribution as derived from the radio core-shift measurements (i.e.,1 , where R is the distance from the central engine and B 1 pc is the magnetic field strength at 1 pc), we further calculate the location of the γ-ray emitting region, g R , for these blazars. We find that~ǵ  R R R 2 10 10 4 S B L R (R S is the Schwarzschild radius and R BLR is the BLR size), where R BLR is estimated from the broad-line luminosities using the empirical correlations obtained using the reverberation mapping methods.

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Catching the radio flare in CTA 102

Cited by 104 publications

References 25 publications

PKS 1502+106: A high-redshiftFermiblazar at extreme angular resolution

PKS 1502+106: A high-redshiftFermiblazar at extreme angular resolution

Multiwavelength observations of the γ-ray flaring quasar S4 1030+61 in 2009–2014

Constraints on the Location of γ-Ray Sample of Blazars with Radio Core-shift Measurements

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