http://arxiv.org/abs/2111.03006
We explore the connection between the $\gamma$-ray and radio emission in the jet of the blazar 0716$+$714 by using 15, 37, and 230 GHz radio and 0.1$-$200 GeV $\gamma$-ray light curves spanning 10.5 years (2008$-$2019). We find significant positive and negative correlations between radio and $\gamma$-ray fluxes in different time ranges. The time delays between radio and $\gamma$-ray emission suggest that the observed $\gamma$-ray flares originated from multiple regions upstream of the radio core, within a few parsecs from the central engine. Using time-resolved 43 GHz VLBA maps we identified 14 jet components moving downstream along the jet. Their apparent speeds range from 6 to 26 $c$, showing notable variations in their position angles upstream the stationary component ($\sim$0.53 mas from the core). The brightness temperature declines as function of distance from the core according to a power-law which becomes shallower at the location of the stationary component. We also find that the periods at which significant correlations between radio and $\gamma$-ray emission occur overlap with the times when the jet was oriented to the north. Our results indicate that the passage of a propagating disturbance (or shock) through the radio core and the orientation of the jet might be responsible for the observed correlation between the radio and $\gamma$-ray variability. We present a scenario that connects the positive correlation and the unusual anti-correlation by combining the production of a flare and a dip at $\gamma$-rays by a strong moving shock at different distances from the jet apex.
D. Kim, E. Kravchenko, A. Kutkin, et. al.
Fri, 5 Nov 21
2/72
Comments: 26 pages, 13 figures, 5 tables, Accepted for publication in ApJ
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