부산대학교 도서관

The nature of the emission region around Sagittarius A* (Sgr A*), the supermassive black hole at the Galactic Center, remains under debate. A prediction of jet models is that a frequency-dependent shift in the position of the radio core (core-shift) of active galactic nucleii occurs when observing emission dominated by a highly collimated relativistic outflow. We use millimeter Very Long Baseline Interferometry to study the frequency-dependent position of Sgr A*'s radio core, estimate the core-shift for different emission models, investigate the core-shift evolution as a function of viewing angle and orientation, and study its behaviour in the presence of interstellar scattering. We simulate images of the emission around Sgr A* for accretion inflow models (disks) and relativistic outflow models (jets). They are based on three-dimensional general relativistic magnetohydrodynamic simulations. We create flux density maps at 22, 43 and 86 GHz sampling different viewing angles and orientations, and examine the effects of scattering. Jet-dominated models show significantly larger core-shifts (in some cases by a factor of 16) than disk-dominated models, intermediate viewing angles (i=30, 45 degrees) show the largest core-shifts. Our jet models follow a power-law relation for the frequency dependent position of Sgr A*'s core. Their core-shifts decrease as the position angle increases from 0 to 90 degrees. Disk models do not fit well a power-law relation and their core-shifts are insensitive to changes in viewing angle. We place an upper limit of 241.65 +-1.93 microarcseconds per cm for the core-shift of jet models including refractive scattering. Our jet models agree with earlier predictions of AGN with conical jets, and the core-shift is retrievable even in the presence of interstellar scattering.