Fuel For Black Holes

An international research team led by Gerd Weigelt from the Max-Planck-Institut fuer Radioastronomie in Bonn reports on high-resolution studies of an active galactic nucleus in the near-infrared. The observations were carried out with the Very Large Telescope Interferometer (VLTI) of the European Southern Observatory (ESO).
The use of near-infrared interferometry allowed the team to resolve a ring-shaped dust distribution (generally called “dust torus”) in the inner region of the nucleus of the active galaxy NGC 3783. This dust torus probably represents the reservoir of gaseous and dusty material that “feeds” the hot gas disk (“accretion disk”) and the supermassive black hole in the center of this galaxy. The resolved dust torus has an angular radius of only 0.7 milliarcseconds on the sky, an angle that is 5 million times smaller than one degree. This angular radius corresponds to a radius of approximately 0.5 light-year for a distance of 130 million light-years. Studies of the physical properties of these dust tori are very important to improve our understanding of their structure and interaction with the accretion disk. To obtain these measurements, the light from up to three telescopes of the Very Large Telescope Interferometer was interferometrically combined. This method is able to achieve an angular resolution equivalent to the resolution of a telescope with a diameter of 130 meters.

Extreme physical processes occur in the innermost regions of galactic nuclei. Supermassive black holes were discovered in many galaxies. The masses of these black holes are often a millionfold larger than the mass of our Sun. These central black holes are surrounded by hot and bright gaseous disks, called “accretion disks”. The emitted radiation from these accretion disks is probably generated by infalling material. To maintain the high luminosity of the accretion disk, fresh material has to be permanently supplied. The dust tori (see Fig. 1) surrounding the accretion disks are most likely the reservoir of the material that flows through the accretion disk and finally “feeds” the growing black hole.

Observations of these dust tori are very challenging since their sizes are very small. A giant telescope with a mirror diameter of more than 100 meters would be able to provide the required angular resolution, but unfortunately telescopes of this size will not be available in the near future. This raises the question: Is there an alternative approach that provides the high resolution required?

The solution is to simultaneously combine (“interfere”) the light from two or more telescopes since these multi-telescope images, which are called interferograms, contain high-resolution information. In the reported NGC 3783 observations, the AMBER interferometry instrument was used to combine the infrared light from two or three telescopes of ESO’s Very Large Telescope Interferometer (VLTI, see Fig. 2). This interferometric method is able to achieve an extreme angular resolution that is proportional to the distance between the telescopes. Since the largest distance between the four telescopes of the VLTI is 130 meters, an angular resolution is obtained that is as high as the theoretical resolution of a telescope with a mirror diameter of 130 meters — a resolution that is 15 times higher than the resolution of one of the VLTI telescopes, which have a mirror diameter of 8 meters.

“The ESO VLTI provides us with a unique opportunity to improve our understanding of active galactic nuclei,”, says Gerd Weigelt from the Max-Planck-Institut fuer Radioastronomie in Bonn. “It allows us to study fascinating physical processes with unprecedented resolution over a wide range of infrared wavelengths. This is needed to derive physical properties of these sources.”

And Makoto Kishimoto emphasizes: “We hope to obtain more detailed information in the next few years by additional observations at shorter wavelengths, with longer baselines, and with higher spectral resolution. Most importantly, in a few years, two further interferometric VLTI instruments will be available, which can provide complementary information.”

To resolve the nucleus of the active galaxy NGC 3783, the research team recorded thousands of two- and three-telescope interferograms with the VLTI. The telescope distances were in the range of 45 to 114 meters. The evaluation of these interferograms allowed the team to derive the radius of the compact dust torus in NGC 3783. A very small angular torus radius of 0.74 milliarcsecond was measured, which corresponds to a radius of 0.52 light-year. These near-infrared radius measurements, together with previously obtained mid-infrared measurements, allowed the team to derive important physical parameters of the torus of NGC 3783.

“The high resolution of the VLTI is also important for studying many other types of astrophysical key objects”, underlines Karl-Heinz Hofmann. “It is clear that infrared interferometry will revolutionize infrared astronomy in a similar way as radio interferometry has revolutionized radio astronomy.”

PIO Contact:
Dr. Norbert Junkes
Press and Public Outreach
Max-Planck-Institut fuer Radioastronomie, Bonn
+49 (0)228-525-399
njunkes@mpifr-bonn.mpg.de

Science Contacts:
Prof. Dr. Gerd Weigelt
Head of Research Group “Infrared Astronomy”
Max-Planck-Institut fuer Radioastronomie, Bonn
+49 (0)228-525-243
gweigelt@mpifr-bonn.mpg.de

Dr. Makoto Kishimoto
Max-Planck-Institut fuer Radioastronomie, Bonn
+49 (0)228-525-189
mk@mpifr-bonn.mpg.de