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Sie sind hier: Startseite Press releases Proto supermassive binary black hole detected in X-rays

Proto supermassive binary black hole detected in X-rays

Based on the article "X-ray detection of the proto supermassive binary black hole at the centre of Abell 400", by Hudson et al. To be published in Astronomy & Astrophysics.

This press release is issued as a collaboration with the University of Bonn, the University of Virginia, the U.S. Naval Research Laboratory, and Astronomy & Astrophysics.

An international team of astronomers led by D. Hudson from Bonn University has detected a proto supermassive binary black hole in images of NASA's Chandra X-ray observatory. Their results will be published in an upcoming issue of Astronomy & Astrophysics.


An international team of astrophysicists, led by D. Hudson from the University of Bonn and including the U.S. Naval Research Laboratory and the University of Virginia, presents their X-ray detection of a proto supermassive binary black hole [1]. Their results will be published in an upcoming issue of Astronomy & Astrophysics. The image of this proto binary black hole was obtained with NASA's Chandra X-ray observatory. The two black holes have already been seen in radio images. The new X-ray images provide unique evidence that these two black holes are in the process of forming a binary system; that is, they are gravitationally bound and orbit each other.

The two black holes are located in the nearby galaxy cluster Abell 400. With high-resolution Chandra data, the team was able to spatially resolve the two supermassive black holes (separated by 15") at the centre of the cluster. Each black hole is located at the centre of its respective host galaxy and the host galaxies appear to be merging.  It is not, however, just the two host galaxies that are colliding - the whole cluster in which they live is merging into another neighbouring galaxy cluster.

Using these new data, the team show that the two black holes are moving through the intracluster medium at the supersonic speed of about 1200 km/s. The wind from such a motion would cause the radio plasma emitted from these two black holes to bend backwards. Although this bending had been observed previously, the cause of it was still being debated. Since the bending of the jets due to this motion is in the same direction, it suggests that the two black holes are travelling along the same path within the cluster and are therefore gravitationally bound.

These two black holes became gravitationally bound when their host galaxies collided. In several million years, the two black holes will probably coalesce causing a burst of gravitational waves, as predicted by Einstein's theory of relativity. This event will produce one of the brightest sources of gravitational radiation in the Universe. Although we will not be around to see this particular one, the observations provide additional evidence that such bound systems exist and are currently merging. The gravitational waves produced by these mergers are believed to be the biggest source of gravitational waves to be detected by the future Laser Interferometer Space Antenna (LISA).

 

Fig. 1. This image shows the central region of the galaxy cluster Abell 400.  The colour coding gives the temperature of the X-ray emitting gas trapped in the cluster: black-cold (18 million degrees Celsius) to white-hot (38 million degrees Celsius). The contours show the radio emission from the jets of plasma being expelled by the black holes. As the two black holes stream through the gas at supersonic velocities, the jets are bent toward the top of the image. The gas in front of the black holes is compressed and heated, as seen by the hotspot below them. The inset shows a blow up of the central regions. Each dot represents a position where an X-ray photon has struck Chandra's X-ray camera. The two black holes are seen as bright regions where as many as 250 X-ray photons struck the camera. The contours again show the radio emission from the black holes and the jets of plasma being ejected from them.

 

Notes to the Editors

[1] The team includes D.S. Hudson (AIfA,Germany), T.H. Reiprich (AIfA,Germany), T.E. Clarke (NRL & Interferometrics Inc.,USA), and C.L. Sarazin (UVa,USA).

X-ray detection of the proto supermassive binary black hole at the centre of Abell 400 by D.S Hudson, T.H. Reiprich, T.E. Clark, and C.L. Sarazin.

To be published in Astronomy & Astrophysics (DOI number:)
Full article available in PDF format.
Electronic edition of the press release available at http://www.edpsciences.org/aa.

 


Contact persons:
*


* Science:

Dr. Daniel Hudson
Email:
dhudson@astro.uni-bonn.de
Phone: 49 228 73 6788

Dr. Thomas Reiprich
Email:
reiprich@astro.uni-bonn.de
Phone: 49 228 73 3642

Dr. Craig L. Sarazin
Email:
sarazin@virginia.edu


* Press office:

Dr. Jennifer Martin
Astronomy & Astrophysics
61, avenue de l'Observatoire
75014 Paris, France
Email: aanda.paris (at) obspm.fr
Phone: +33 1 43 29 05 41

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