# The June 2016 Optical and Gamma-Ray Outburst and Optical   Micro-Variability of the Blazar 3C454.3

**Authors:** Zachary R. Weaver, Thomas J. Balonek, Svetlana G. Jorstad, Alan P., Marscher, Valeri M. Larionov, Paul S. Smith, Samantha J. Boni, George A., Borman, K.J. Chapman, Leah G. Jenks, Evgenia N. Kopatskaya, Elena G., Larionova, Daria A. Morozova, Anna A. Nikiforova, Alina Sabyr, Sergey S., Savchenko, Ryan W. Stahlin, Yulia V. Troitskaya, Ivan S. Troitsky, and, Saiyang Zhang

arXiv: 1903.04587 · 2019-04-17

## TL;DR

The paper reports on a detailed multi-frequency observation of the June 2016 outburst of blazar 3C454.3, revealing rapid flux decay, micro-variability oscillations, polarization changes, and jet ejection dynamics.

## Contribution

This study provides the first detailed analysis of the micro-variability and polarization behavior during a major outburst of 3C454.3, linking optical and gamma-ray observations with jet activity.

## Key findings

- Maximum flux observed on June 24, 2016, in optical and gamma-ray bands.
- Detected quasi-periodic micro-variability oscillations with a 36-minute period.
- Ejection of a jet knot at 20.3c apparent speed.

## Abstract

The quasar 3C454.3 underwent a uniquely-structured multi-frequency outburst in June 2016. The blazar was observed in the optical $R$ band by several ground-based telescopes in photometric and polarimetric modes, at $\gamma$-ray frequencies by the \emph{Fermi}\ Large Area Telescope, and at 43 GHz with the Very Long Baseline Array. The maximum flux density was observed on 2016 June 24 at both optical and $\gamma$-ray frequencies, reaching $S^\mathrm{max}_\mathrm{opt}=18.91\pm0.08$ mJy and $S_\gamma^\mathrm{max} =22.20\pm0.18\times10^{-6}$ ph cm$^{-2}$ s$^{-1}$, respectively. The June 2016 outburst possessed a precipitous decay at both $\gamma$-ray and optical frequencies, with the source decreasing in flux density by a factor of 4 over a 24-hour period in $R$ band. Intraday variability was observed throughout the outburst, with flux density changes between 1 and 5 mJy over the course of a night. The precipitous decay featured statistically significant quasi-periodic micro-variability oscillations with an amplitude of $\sim 2$-$3\%$ about the mean trend and a characteristic period of 36 minutes. The optical degree of polarization jumped from $\sim3\%$ to nearly 20\% during the outburst, while the position angle varied by $\sim120\degr$. A knot was ejected from the 43 GHz core on 2016 Feb 25, moving at an apparent speed $v_\mathrm{app}=20.3c\pm0.8c$. From the observed minimum timescale of variability $\tau_\mathrm{opt}^\mathrm{min}\approx2$ hr and derived Doppler factor $\delta=22.6$, we find a size of the emission region $r\lesssim2.6\times10^{15}$ cm. If the quasi-periodic micro-variability oscillations are caused by periodic variations of the Doppler factor of emission from a turbulent vortex, we derive a rotational speed of the vortex $\sim0.2c$.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1903.04587/full.md

## Figures

19 figures with captions in the complete paper: https://tomesphere.com/paper/1903.04587/full.md

## References

67 references — full list in the complete paper: https://tomesphere.com/paper/1903.04587/full.md

---
Source: https://tomesphere.com/paper/1903.04587