The kinematics of superluminal components in blazar 3C 454.3 are studied.Nine components are included: superluminal knots R1, R2, R3, R4, A, B, C and D(from Britzen et al. 2013) and C4 (from Pauliny-Toth 1998). W...The kinematics of superluminal components in blazar 3C 454.3 are studied.Nine components are included: superluminal knots R1, R2, R3, R4, A, B, C and D(from Britzen et al. 2013) and C4 (from Pauliny-Toth 1998). We find that their kine-matics derived from VLBI observations can be consistently interpreted in terms of ajet precession scenario with a period of about 14.5 yr. We discuss the model fits oftheir trajectory, distance from the core and apparent velocity. We show that the bulkLorentz factor (in the range 4 to 15) derived for these components does not have anydependence on the phase of the precession (or position angle for ejection). The Lense-Thirring effect is assumed to interpret the precession of the jet nozzle. The resultsobtained for blazar 3C 454.3 are only suggestive. They are not unique and have yet tobe tested, but they might be useful for understanding the kinematics of superluminalcomponents in blazars and for disentangling different mechanisms and factors.展开更多
It is proved that the apparent transverse velocities β<sub>app</sub> and the spectral powers at 10GHz P<sub>10</sub> of the cores of known superluminal sources are correlated. An interpretatio...It is proved that the apparent transverse velocities β<sub>app</sub> and the spectral powers at 10GHz P<sub>10</sub> of the cores of known superluminal sources are correlated. An interpretation ofthis result within the framework of the relativistic jet model shows that the jet Lorentzfactor γ depends on the intrinsic luminosity of the sources. The probable existence of twosubpopulations of the superluminal sources is shown by a linear regression analysis. "Small"sources f i.e. the sources without extended emission or with a distance from the core tothe outer edge of the lobe【20 kpc, show lower β<sub>app</sub> than the "large" objects; this can beinterpreted as an orientation effect. Since all BL Lac objects belong to the "small" class,this result sheds new light on such a question as why these sources have lower apparent ve-locities than the "classical" superluminal quasars.展开更多
文摘The kinematics of superluminal components in blazar 3C 454.3 are studied.Nine components are included: superluminal knots R1, R2, R3, R4, A, B, C and D(from Britzen et al. 2013) and C4 (from Pauliny-Toth 1998). We find that their kine-matics derived from VLBI observations can be consistently interpreted in terms of ajet precession scenario with a period of about 14.5 yr. We discuss the model fits oftheir trajectory, distance from the core and apparent velocity. We show that the bulkLorentz factor (in the range 4 to 15) derived for these components does not have anydependence on the phase of the precession (or position angle for ejection). The Lense-Thirring effect is assumed to interpret the precession of the jet nozzle. The resultsobtained for blazar 3C 454.3 are only suggestive. They are not unique and have yet tobe tested, but they might be useful for understanding the kinematics of superluminalcomponents in blazars and for disentangling different mechanisms and factors.
基金Supported by the National Natural Science Foundation of China and an honorarium provided by the MPG.
文摘It is proved that the apparent transverse velocities β<sub>app</sub> and the spectral powers at 10GHz P<sub>10</sub> of the cores of known superluminal sources are correlated. An interpretation ofthis result within the framework of the relativistic jet model shows that the jet Lorentzfactor γ depends on the intrinsic luminosity of the sources. The probable existence of twosubpopulations of the superluminal sources is shown by a linear regression analysis. "Small"sources f i.e. the sources without extended emission or with a distance from the core tothe outer edge of the lobe【20 kpc, show lower β<sub>app</sub> than the "large" objects; this can beinterpreted as an orientation effect. Since all BL Lac objects belong to the "small" class,this result sheds new light on such a question as why these sources have lower apparent ve-locities than the "classical" superluminal quasars.
