Astrophysical phenomena related to supermassive black holes - Searching for local particularities in the center of the Milky Way and extragalactic nuclei at high angular resolution
All projects aim at pushing the limits of our knowledge about the interaction between a galaxy and a supermassive black hole (SMBH) at its center. The development of a new instrument can be as valuable as combining different datasets. I follow both approaches and developed projects which deal with new instrumentation and telescope technology, combine datasets from different wavelengths and resolutions, and incorporate recent theoretical models and predictions, which can be verified empirically. The first two of the six chapters compile astrophysical and technical background of the individual projects, which are presented in the following four chapters. While the first project (Chapter 3) deals with observations of the innermost parsec of our Galaxy, Chapter 4 presents data of the inner kpc of an active galaxy. The subjects of Chapters 5 and 6 are very luminous AGN/host systems, so-called QSOs. Whereas Chapter 5 presents global, spatially unresolved properties of SMBH/host systems, the radio jet, analyzed in the final Chapter 6, combines all size scales. It is investigated from close to its origin out to several kpc. The accretion onto the black hole of the Milky Way (Chapter 3) is extremely inefficient and the SMBH possibly interacts dominantly via tidal forces only. The next discussed system (Chapter 4) is the prototype of moderately luminous Seyfert 2 AGN, NGC 1068. Here a strong local influence of the nuclear X-ray radiation is observed. Chapter 5 deals with the possible global importance of radiative interaction between highly luminous QSO AGN and the host. The radio jet in Chapte 6 definitely shows signs of interaction with the matter of its host several kpc away from the nucleus. Chapters 3-6 include a dedicated introductory and a conclusive section, which put the results obtained in the larger astrophysical context of the observation. Chapter 3 deals with the pioneering interferometric infrared study of stellar sources and their surroundings in the immediate vicinity of the SMBH at the center of the Milky Way. I was able to use the resolving power of an optical large baseline interferometer (OLBI) to investigate for the first time the different structures and excitation conditions of interstellar and circumstellar dust in 200 mpc distance to the SMBH. It is unknown whether the standard models for star and dust formation, which themselves dominate the infrared appearance of an inactive galaxy as the Milky Way, still apply under the strong tidal forces of gravity, exerted by the central SMBH. The VLTI observations, described in Chapter 3, are the first observations of stellar interferometry in the infrared, which target objects through the 25 magnitudes of optical extinction along the line of sight toward the GC. One motivation for these observations, in addition to the direct scientific intention, was to create a showcase for advanced optical interferometry applications at the GC. An important part of the thesis is the detailed analysis of the achievable accuracy of the interferometric measurements. Such a precision study under the challenging conditions of off-axis optical AO guiding and faint target brightnesses close to the system limits has not been published before. For the first time I can present results that show that the direct zone of dust formation around the deeply embedded star is observable. The temperature, derived from the spectral properties, and the spatial size, as derived from the high resolution interferometric dataset, show the cool star nature of the object. The following Chapter 4 reports on the first extragalactic sub-mm spectra of the innermost region in the Seyfert 2 prototype NGC 1068 with the new APEX telescope facility. The emission of the molecular rotational excitation lines CO(J=3-2) and HCN(J=4-3) were observed during the instrument testing phase. In Chapter 5, I present the results of the search for rotational line transitions at 80 GHz, in particular the 1-0 transition of the HCN molecule. It traces gas densities larger than 10^4 cm^-3 and is therefore a better quantitative tracers of the regions where star formation actually occurs than the stronger CO(1-0) transition, which correlates to the total amount of molecular gas which could be transformed into stars. The observed galaxies host a luminous quasar in their core. I investigate the hypothesis of an amplification and extension of this effect in high luminosity AGN from local nuclear to global galactic scales. In the last chapter, I analyze the physical properties of the radio jet in the radio loud quasar J1101+7225, which shows exceptionally far away from its nuclear origin (4 kpc) high relativistic motions. I follow the jet down to the hundred pc scale. The full analysis of the radio properties reveals an exemplary radio jet, which shows a complex inner structure including a possibly helical morphology
