Optical polarization of high-energy BL Lac objects

TL;DR

This study compares the optical polarization properties of high-energy BL Lac objects with and without TeV detection, finding no intrinsic differences and suggesting TeV detection relates more to flaring activity and spectral properties.

Contribution

It provides the first detailed comparison of polarization characteristics between TeV-detected and non-TeV high-energy BL Lac objects, highlighting the lack of intrinsic polarization differences.

Findings

No intrinsic polarization differences between TeV and non-TeV sources.

TeV detection correlates with flaring activity, redshift, and spectral peak, not polarization.

Significant EVPA rotations occur in both source types, compatible with a random walk process.

Abstract

We investigate the optical polarization properties of high-energy BL Lac objects using data from the RoboPol blazar monitoring program and the Nordic Optical Telescope. We wish to understand if there are differences in the BL Lac objects that are detected with the current-generation TeV instruments compared to those that have not yet been detected. The mean polarization fraction of the TeV-detected BL Lacs is 5% while the non-TeV sources show a higher mean polarization fraction of 7%. This difference in polarization fraction disappears when the dilution by the unpolarized light of the host galaxy is accounted for. The TeV sources show somewhat lower fractional polarization variability amplitudes than the non-TeV sources. Also the fraction of sources with a smaller spread in the Q/I - U/I -plane and a clumped distribution of points away from the origin, possibly indicating a preferred polarization angle, is larger in the TeV than in the non-TeV sources. These differences between TeV and non-TeV samples seems to arise from differences between intermediate and high spectral peaking sources instead of the TeV detection. When the EVPA variations are studied, the rate of EVPA change is similar in both samples. We detect significant EVPA rotations in both TeV and non-TeV sources, showing that rotations can occur in high spectral peaking BL Lac objects when the monitoring cadence is dense enough. Our simulations show that we cannot exclude a random walk origin for these rotations. These results indicate that there are no intrinsic differences in the polarization properties of the TeV-detected and non-TeV-detected high-energy BL Lac objects. This suggests that the polarization properties are not directly related to the TeV-detection, but instead the TeV loudness is connected to the general flaring activity, redshift, and the synchrotron peak location. (Abridged)