The NASA image of the day shows the supermassive black hole at the center of spiral galaxy M81.
At the center of the spiral galaxy M81 is a supermassive black hole about 70 million times more massive than our sun.
A study using data from Chandra and ground-based telescopes, combined with detailed theoretical models, shows that the supermassive black hole in M81 feeds just like stellar mass black holes, with masses of only about ten times that of the sun. This discovery supports Einstein’s relativity theory that states black holes of all sizes have similar properties.
Publication: Sera Markoff, et al., “Results from an Extensive Simultaneous Broadband Campaign on the Underluminous Active Nucleus M81*: Further Evidence for Mass-scaling Accretion in Black Holes,” The Astrophysical Journal, 681 (2008) 905; doi:10.1086/588718
Reference: “Results from an Extensive Simultaneous Broadband Campaign on the Underluminous Active Nucleus M81*: Further Evidence for Mass-scaling Accretion in Black Holes” by Sera Markoff, Michael Nowak, Andrew Young, Herman L. Marshall, Claude R. Canizares, Alison Peck, Melanie Krips, Glen Petitpas, Rainer Schödel, Geoffrey C. Bower, Poonam Chandra, Alak Ray, Michael Muno, Sarah Gallagher, Seth Hornstein and Chi C. Cheung, 10 July 2008, The Astrophysical Journal.
The biggest black holes may feed just like the smallest ones, according to data from NASA’s Chandra X-ray Observatory and ground-based telescopes. This discovery supports the implication of Einstein’s relativity theory that black holes of all sizes have similar properties, and will be useful for predicting the properties of a conjectured new class of black holes.
The conclusion comes from a large observing campaign of the spiral galaxy M81, which is about 12 million light-years from Earth. In the center of M81 is a black hole that is about 70 million times more massive than the Sun, and generates energy and radiation as it pulls gas in the central region of the galaxy inwards at high speed.
In contrast, so-called stellar mass black holes, which have about 10 times more mass than the Sun, have a different source of food. These smaller black holes acquire new material by pulling gas from an orbiting companion star. Because the bigger and smaller black holes are found in different environments with different sources of material to feed from, a question has remained about whether they feed in the same way.
Using these new observations and a detailed theoretical model, a research team compared the properties of M81’s black hole with those of stellar mass black holes. The results show that either big or little, black holes indeed appear to eat similarly to each other, and produce a similar distribution of X-rays, optical, and radio light.
One of the implications of Einstein’s theory of General Relativity is that black holes are simple objects and only their masses and spins determine their effect on space-time. The latest research indicates that this simplicity manifests itself in spite of complicated environmental effects.
“This confirms that the feeding patterns for black holes of different sizes can be very similar,” said Sera Markoff of the Astronomical Institute, University of Amsterdam in the Netherlands, who led the study. “We thought this was the case, but up until now we haven’t been able to nail it.”
The model that Markoff and her colleagues used to study the black holes includes a faint disk of material spinning around the black hole. This structure would mainly produce X-rays and optical light. A region of hot gas around the black hole would be seen largely in ultraviolet and X-ray light. A large contribution to both the radio and X-ray light comes from jets generated by the black hole. Multi-wavelength data is needed to disentangle these overlapping sources of light.
“When we look at the data, it turns out that our model works just as well for the giant black hole in M81 as it does for the smaller guys,” said Michael Nowak, a coauthor from the Massachusetts Institute of Technology. “Everything around this huge black hole looks just the same except it’s almost 10 million times bigger.”
Among actively feeding black holes the one in M81 is one of the dimmest, presumably because it is “underfed”. It is, however, one of the brightest as seen from Earth because of its relative proximity, allowing high quality observations to be made.
“It seems like the underfed black holes are the simplest in practice, perhaps because we can see closer to the black hole,” said Andrew Young of the University of Bristol in England. “They don’t seem to care too much where they get their food from.”
This work should be useful for predicting the properties of a third, unconfirmed class called intermediate-mass black holes, with masses lying between those of stellar and supermassive black holes. Some possible members of this class have been identified, but the evidence is controversial, so specific predictions for the properties of these black holes should be very helpful.
In addition to Chandra, three radio arrays (the Giant Meterwave Radio Telescope, the Very Large Array and the Very Long Baseline Array), two-millimeter telescopes (the Plateau de Bure Interferometer and the Submillimeter Array), and Lick Observatory in the optical were used to monitor M81. These observations were made simultaneously to ensure that brightness variations because of changes in feeding rates did not confuse the results. Chandra is the only X-ray satellite able to isolate the faint X-rays of the black hole from the emission of the rest of the galaxy.
This result confirms less detailed earlier work by Andrea Merloni from the Max Planck Institute for Extraterrestrial Physics (MPE) in Garching, Germany, and colleagues that suggested that the basic properties of larger black holes are similar to the smaller ones. Their study, however, was not based on simultaneous, multi-wavelength observations nor the application of a detailed physical model.
These results will appear in an upcoming issue of The Astrophysical Journal. NASA’s Marshall Space Flight Center, Huntsville, Alabama, manages the Chandra program for the agency’s Science Mission Directorate. The Smithsonian Astrophysical Observatory controls science and flight operations from the Chandra X-ray Center in Cambridge, Massachusetts.