The effects of relativistic bulk motion of X-ray flares in the corona on the iron Kalpha line in Seyfert 1 galaxies
Abstract
We study the effects of the bulk motion of X-ray flares on the shape and equivalent width of the iron Kalpha line from an untruncated cold disk around a Kerr black hole using fully relativistic calculations. The flares are located above a cold accretion disk -- either on or off the rotation axis. For on- or off-axis flares, the upward/outward bulk motion causes a reduction of the iron Kalpha line width. To a distant observer with a low inclination angle (θo 30deg.), larger upward/outward bulk velocities decrease the extension of the red wing, with little change in the location of the blue `edge'. In contrast, an observer at a large inclination angle (e.g. θo=60deg.) sees both the red wing and the blue `edge' change with the bulk velocity. The equivalent width of the iron Kalpha line decreases rapidly with increasing bulk velocity of flares. However, the `narrower' line profiles observed in some objects (e.g. IC4329A and NGC4593) are difficult to produce using the out-flowing magnetic flare model with an appropriate equivalent width unless the X-ray emission is concentrated in an outer region with a radius of several tens of rg=GM/c2 or more. An important result is that the iron Kalpha line intensity is found to be constant even though the continuum flux varies significantly, which is true for out-flowing magnetic flares with different bulk velocities but similar intrinsic luminosities when located close to the central black hole. We find that fluctuations in the bulk velocities of out-flowing low-height flares located at the inner region (r 15rg) can account for a constant iron Kalpha line and significant continuum variation as observered in MCG-6-30-15 and NGC5548. (Abridged)
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