Milliarcsecond Core Size Dependence of the Radio Variability of Blazars

TL;DR

This study investigates how the milliarcsecond core sizes of blazars influence their long-term radio variability, revealing that more compact cores exhibit larger and faster variability, with correlations extending across multiple frequencies.

Contribution

It provides the first comprehensive analysis linking milliarcsecond core sizes to radio variability amplitudes and timescales across multiple frequencies in a large blazar sample.

Findings

Compact cores show larger variability amplitudes.

Shorter variability timescales are associated with smaller core sizes.

Correlation between core size and variability extends across frequencies.

Abstract

Studying the long-term radio variability (timescales of months to years) of blazars enables us to gain a better understanding of the physical structure of these objects on sub-parsec scales, and the physics of super massive black holes. In this study, we focus on the radio variability of 1157 blazars observed at 15 GHz through the Owens Valley Radio Observatory (OVRO) Blazar Monitoring Program. We investigate the dependence of the variability amplitudes and timescales, characterized based on model fitting to the structure functions, on the milliarcsecond core sizes measured by Very Long Baseline Interferometry. We find that the most compact sources at milliarcsecond scales exhibit larger variability amplitudes and shorter variability timescales than more extended sources. Additionally, for sources with measured redshifts and Doppler boosting factors, the correlation between linear core sizes against variability amplitudes and intrinsic timescales are also significant. The observed relationship between variability timescales and core sizes is expected, based on light travel-time arguments. This variability vs core size relation extends beyond the core sizes measured at 15 GHz; we see significant correlation between the 15 GHz variability amplitudes (as well as timescales) and core sizes measured at other frequencies, which can be attributed to a frequency-source size relationship arising from the intrinsic jet structure. At low frequencies of 1 GHz where the core sizes are dominated by interstellar scattering, we find that the variability amplitudes have significant correlation with the 1 GHz intrinsic core angular sizes, once the scatter broadening effects are deconvoluted from the intrinsic core sizes.