On the geometrical origin of periodicity in blazar-type sources
Abstract
Periodicities in blazar light curves may be related to helical trajectories in extragalactic radio jets by differential Doppler boosting effects. We consider ballistic and non-ballistic (i.e., radial) trajectories and discuss three possible periodic driving mechanisms for the origin of helical jet paths, namely, orbital motion in a binary black hole system (BBHS), jet precession, and intrinsic jet rotation. It is shown that precessional-driven ballistic motion is unlikely to result in observable periods of less than several tens of years. We demonstrate that for non-ballistic helical motion the observed period is generally strongly shortened relative to the real physical driving period because of light-travel time effects. Internal jet rotation may thus account for observed periods P obs ≤ 10 days. Periodicity due to orbital-driven (non-ballistic) helical motion, on the other hand, is usually constrained to periods of P obs ≥ 10 days, while Newtonian-driven precession is unlikely to be responsible for periodicity on a timescale P obs ≤ 100 days but may well be associated with periods of P obs ≥ 1 yr.
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