X-ray Radiation Mechanisms and Beaming Effect of Hot Spots and Knots in Active Galactic Nuclear Jets

Abstract

The observed radio-optical-X-ray spectral energy distributions (SEDs) of 22 hot spots and 45 knots in the jets of 35 active galactic nuclei are complied from literature and modeled with single-zone lepton models. It is found that the observed luminosities at 5 GHz (L5GHz) and at 1 keV (L1keV) are tightly correlated, and the two kinds of sources can be roughly separated with a division of L1keV=L5GHz. Our SED fits show that the mechanisms of the X-rays are diverse. Considering the sources at rest, the synchrotron-self-Compton (SSC) scattering would dominate the IC process. This model can interpret the X-rays of some hot spots with a magnetic field strength (Bsscdelta=1) being consistent with the equipartition magnetic field (Beqdelta=1) in one order of magnitude, but an unreasonably low Bsscdelta=1 is required to model the X-rays for all knots. The ratio RB=Beqdelta=1/Bsscdelta=1 is greater than 1 and it is tightly anti-correlated with ratio RL= L1keV/L5GHz for both the knots and the hot spots. We propose that the deviation may be due to the neglect of the relativistic bulk motion for these sources. Considering this effect, we show that the IC/CMB model well explains the X-ray emission for most sources. Both Beq' and delta are tentatively correlated with RL. Corrected by the beaming effect, the L'5GHz-L'1keV relations for the two kinds of sources are even tighter than the observed ones. These facts suggest that, under the equipartition condition, the observational differences of the X-rays from the knots and hot spots may be mainly due the differences on the Doppler boosting effect and the co-moving magnetic field of the two kinds of sources. Our IC scattering models predict a prominent GeV-TeV component in the SEDs for some sources, which are detectable with H.E.S.S. and Fermi/LAT.