Black hole without a home
The detection of a super-massive black hole without a massive 'host' galaxy is the surprising result from a large Hubble and VLT study of quasars.
This is the first convincing discovery of such an object. One intriguing explanation is that the host galaxy may be made almost exclusively of 'dark matter'.
A team of European astronomers has used two of the most powerful astronomical facilities available, the NASA/ESA Hubble Space Telescope and the ESO Very Large Telescope (VLT) at Cerro Paranal, to discover a bright quasar without a massive host galaxy.
Quasars are powerful and typically very distant source of huge amounts of radiation. They are commonly associated with galaxies containing an active central black hole.
The team conducted a detailed study of 20 relatively nearby quasars. For 19 of them, they found, as expected, that these super-massive black holes are surrounded by a host galaxy. But when they studied the bright quasar HE0450-2958, located some 5000 million light-years away, they could not find evidence for a host galaxy.
The astronomers suggest that this may indicate a rare case of a collision between a seemingly normal spiral galaxy and an 'exotic' object harbouring a very massive black hole.
With masses that are hundreds of millions times bigger than the Sun, super-massive black holes are commonly found in the centres of the most massive galaxies, including our own Milky Way. These black holes sometimes dramatically manifest themselves by devouring matter that they gravitationally swallow from their surroundings.
The best fed of these objects shine as 'quasars' (standing for 'quasi-stellar object' because they had initially been thought of as stars).
The past decade of observations, largely with the Hubble telescope, has shown that quasars are normally associated with massive host galaxies. However, observing the host galaxy of a quasar is challenging work because the quasar completely outshines the host and masks the galaxy’s underlying structure.
To overcome this problem, the astronomers devised a new and highly efficient strategy. Combining Hubble’s ultra-sharp images and spectroscopy from ESO’s VLT, they observed their sample of 20 quasars at the same time as a reference star. The star served as a reference pinpoint light source that was used to disentangle the quasar light from any possible light from an underlying galaxy.
Despite the innovative techniques used, no host galaxy was seen around HE0450-2958. This means that if any host galaxy exists, it must either be at least six times fainter than typical host galaxies, or have a radius smaller than about 300 light-years, i.e. 20 to 170 times smaller than typical host galaxies (which normally have radii ranging from about 6000 to 50 000 light-years).
"With the powerful combination of Hubble and the VLT we are confident that we would have been able to detect a normal host galaxy," said Pierre Magain of the Université de Liège, Belgium.
The astronomers did however detect an interesting smaller cloud of gas about 2500 light-years wide near the quasar, which they call 'the blob'. VLT observations show this cloud to be glowing because it is bathed in the intense radiation coming from the quasar, and not from stars inside the cloud. Most likely, it is the gas from this cloud that feeds the super-massive black hole, thereby allowing it to become a quasar.
The left image above shows a strongly disturbed galaxy, with all the signs of a recent collision, near the quasar. The VLT observations show it to be forming stars at a great rate.
"The absence of a massive host galaxy, combined with the existence of the blob and the star-forming galaxy, lead us to believe that we have uncovered a really exotic quasar," said Frédéric Courbin of the Ecole Polytechnique Federale de Lausanne, Switzerland.
"There is little doubt that an increase in the formation of stars in the companion galaxy and the quasar itself have been ignited by a collision that must have taken place about 100 million years ago. What happened to the putative quasar host remains unknown."
HE0450-2958 is a challenging case. The astronomers propose several possible explanations. Has the host galaxy been completely disrupted as a result of the collision? Has an isolated black hole captured gas while crossing the disk of a spiral galaxy? This would require very special conditions and would probably not have caused such a tremendous disturbance of the neighbouring galaxy as is observed. Further studies will hopefully clarify the situation.
Another intriguing hypothesis is that the galaxy harbouring the black hole was almost exclusively made of 'dark matter'. It may be that what is observed is a normal phase in the formation of a massive galaxy, which in this case has taken place several 1000 million years later than in most others.
For more information:
The paper on HE0450-2958 is published in the 15 September 2005 issue of the journal Nature.
Frédéric Courbin/Pascale Jablonka
Laboratoire d'Astrophysique, Ecole Polytechnique Federale de Lausanne, Switzerland
Tel: +41 22 379 2418 / +41 22 379 2469
E-mail: frederic.courbin @ epfl.ch / pascale.jablonka @ obs.unige.ch
Institut d'Astrophysique de Geophysique, Universite de Liege, Belgium
Tel: +32 4366 97 53
E-mail: Pierre.Magain @ ulg.ac.be
Astrophysikalisches Institut Potsdam, Germany
Tel: +49 331 7499532
E-mail: lwisotzki @ aip.de
Lars Lindberg Christensen
Hubble European Space Agency Information Centre, Garching, Germany
Tel: +49 89 3200 6306
Mobile +49 173 3872 621
E-mail: lars @ eso.org
Henri Boffin European Southern Observatory
Tel: +49 89 3200 6222
E-mail: hboffin @ eso.org
Ray Villard Space Telescope Science Institute, Baltimore, USA
Tel: +1 410 338 4514
E-mail: villard @ stsci.edu
The full team is: Pierre Magain, Géraldine Letawe (Univ. Liege, Belgium), Frederic Courbin, Georges Meylan (Ecole Polytechnique Federale de Lausanne (EPFL), Switzerland), Pascale Jablonka (EPFL; also affiliated to Univ. Geneve), Knud Jahnke and Lutz Wisotzki (Astrophysikalisches Institut Potsdam, Germany).