A galactic crash investigation

By examining one of the most complex and unusual colliding clusters in the sky, astronomers have pieced together the history of a cosmic crash that took place over a period of 350 million years.
By | Published: June 22, 2011 | Last updated on May 18, 2023
Abell 2744
This image combines visible light exposures of galaxy cluster Abell 2744 taken by the NASA/ESA Hubble Space Telescope and the European Southern Observatory’s Very Large Telescope, with X-ray data from NASA’s Chandra X-ray Observatory and a mathematical reconstruction of the location of dark matter. NASA/ESA/ESO/CXC/D. Coe (STScI)/J. Merten (Heidelberg/Bologna)
A team of scientists has studied the galaxy cluster Abell 2744, nicknamed Pandora’s Cluster. The group has pieced together the cluster’s complex and violent history using telescopes in space and on the ground, including the European Space Observatory’s (ESO) Very Large Telescope (VLT) and the Hubble Space Telescope. Abell 2744 seems to be the result of a simultaneous pileup of at least four separate galaxy clusters, and this complex collision has produced strange effects that have never been seen together before.

When huge clusters of galaxies crash together, the resulting mess is a treasure-trove of information for astronomers. By investigating one of the most complex and unusual colliding clusters in the sky, an international team of astronomers has pieced together the history of a cosmic crash that took place over a period of 350 million years.

“Like a crash investigator piecing together the cause of an accident, we can use observations of these cosmic pileups to reconstruct events that happened over a period of hundreds of millions of years,” said Julian Merten from the Institute for Theoretical Astrophysics in Heidelberg, Germany. “This can reveal how structures form in the universe, and how different types of matter interact with each other when they are smashed together.”

“We nicknamed it Pandora’s Cluster because so many different and strange phenomena were unleashed by the collision. Some of these phenomena had never been seen before,” said Renato Dupke from the University of Michigan in Ann Arbor.

Abell 2744 has now been studied in more detail than ever before by combining data from ESO’s VLT, the Japanese Subaru telescope, the NASA/ESA Hubble Space Telescope, and NASA’s Chandra X-Ray Observatory.

The galaxies in the cluster are clearly visible in the VLT and Hubble images. Although the galaxies are bright, they make up less than 5 percent of the mass. The rest is gas (around 20 percent), which is so hot that it shines only in X-rays, and dark matter (around 75 percent), which is completely invisible. To understand what was going on in the collision, the team needed to map the positions of all three types of matter in Abell 2744.

Dark matter is particularly elusive as it does not emit, absorb, or reflect light, but only makes itself apparent through its gravitational attraction. To pinpoint the location of this mysterious substance, the team exploited a phenomenon known as gravitational lensing. This is the bending of light rays from distant galaxies as they pass through the gravitational fields present in the cluster. The result is a series of telltale distortions in the images of galaxies in the background of the VLT and Hubble observations. By carefully plotting the way that these images are distorted, it is possible to map quite accurately where the hidden mass — and hence the dark matter — actually lies.

By comparison, finding the hot gas in the cluster is simpler as NASA’s Chandra X-ray Observatory can observe it directly. These observations are not just crucial to find out where the gas is, but also to show the angles and speeds at which different components of the cluster came together.

When the astronomers looked at the results, they found many curious features. “Abell 2744 seems to have formed from four different clusters involved in a series of collisions over a period of about 350 million years. The complicated and uneven distribution of the different types of matter is extremely unusual and fascinating,” said Dan Coe from the Space Telescope Science Institute in Baltimore, Maryland.

It seems that the complex collision has separated out some of the hot gas and dark matter so that they now lie apart from each other and from the visible galaxies. Pandora’s Cluster combines several phenomena that have only been seen singly in other systems.

Near the core of the cluster is a “bullet,” where the gas of one cluster collided with that of another to create a shock wave. The dark matter passed through the collision unaffected.

In another part of the cluster, there seem to be galaxies and dark matter, but no hot gas. The gas may have been stripped away during the collision, leaving behind no more than a faint trail.

Even odder features lie in the outer parts of the cluster. One region contains lots of dark matter, but no luminous galaxies or hot gas. A separate ghostly clump of gas has been ejected, which precedes rather than follows the associated dark matter. This puzzling arrangement may be telling astronomers something about how dark matter behaves and how the various ingredients of the universe interact with each other.

Galaxy clusters are the biggest structures in the cosmos, containing literally trillions of stars. The way they form and develop through repeated collisions has profound implications for our understanding of the universe. Further studies of the Pandora’s Cluster, the most complex and fascinating merger yet found, are in progress.

A team of scientists has studied the galaxy cluster Abell 2744, nicknamed Pandora’s Cluster. The group has pieced together the cluster’s complex and violent history using telescopes in space and on the ground, including the European Space Observatory’s (ESO) Very Large Telescope (VLT) and the Hubble Space Telescope. Abell 2744 seems to be the result of a simultaneous pileup of at least four separate galaxy clusters, and this complex collision has produced strange effects that have never been seen together before.

When huge clusters of galaxies crash together, the resulting mess is a treasure-trove of information for astronomers. By investigating one of the most complex and unusual colliding clusters in the sky, an international team of astronomers has pieced together the history of a cosmic crash that took place over a period of 350 million years.

“Like a crash investigator piecing together the cause of an accident, we can use observations of these cosmic pileups to reconstruct events that happened over a period of hundreds of millions of years,” said Julian Merten from the Institute for Theoretical Astrophysics in Heidelberg, Germany. “This can reveal how structures form in the universe, and how different types of matter interact with each other when they are smashed together.”

“We nicknamed it Pandora’s Cluster because so many different and strange phenomena were unleashed by the collision. Some of these phenomena had never been seen before,” said Renato Dupke from the University of Michigan in Ann Arbor.

Abell 2744 has now been studied in more detail than ever before by combining data from ESO’s VLT, the Japanese Subaru telescope, the NASA/ESA Hubble Space Telescope, and NASA’s Chandra X-Ray Observatory.

The galaxies in the cluster are clearly visible in the VLT and Hubble images. Although the galaxies are bright, they make up less than 5 percent of the mass. The rest is gas (around 20 percent), which is so hot that it shines only in X-rays, and dark matter (around 75 percent), which is completely invisible. To understand what was going on in the collision, the team needed to map the positions of all three types of matter in Abell 2744.

Dark matter is particularly elusive as it does not emit, absorb, or reflect light, but only makes itself apparent through its gravitational attraction. To pinpoint the location of this mysterious substance, the team exploited a phenomenon known as gravitational lensing. This is the bending of light rays from distant galaxies as they pass through the gravitational fields present in the cluster. The result is a series of telltale distortions in the images of galaxies in the background of the VLT and Hubble observations. By carefully plotting the way that these images are distorted, it is possible to map quite accurately where the hidden mass — and hence the dark matter — actually lies.

By comparison, finding the hot gas in the cluster is simpler as NASA’s Chandra X-ray Observatory can observe it directly. These observations are not just crucial to find out where the gas is, but also to show the angles and speeds at which different components of the cluster came together.

When the astronomers looked at the results, they found many curious features. “Abell 2744 seems to have formed from four different clusters involved in a series of collisions over a period of about 350 million years. The complicated and uneven distribution of the different types of matter is extremely unusual and fascinating,” said Dan Coe from the Space Telescope Science Institute in Baltimore, Maryland.

It seems that the complex collision has separated out some of the hot gas and dark matter so that they now lie apart from each other and from the visible galaxies. Pandora’s Cluster combines several phenomena that have only been seen singly in other systems.

Near the core of the cluster is a “bullet,” where the gas of one cluster collided with that of another to create a shock wave. The dark matter passed through the collision unaffected.

In another part of the cluster, there seem to be galaxies and dark matter, but no hot gas. The gas may have been stripped away during the collision, leaving behind no more than a faint trail.

Even odder features lie in the outer parts of the cluster. One region contains lots of dark matter, but no luminous galaxies or hot gas. A separate ghostly clump of gas has been ejected, which precedes rather than follows the associated dark matter. This puzzling arrangement may be telling astronomers something about how dark matter behaves and how the various ingredients of the universe interact with each other.

Galaxy clusters are the biggest structures in the cosmos, containing literally trillions of stars. The way they form and develop through repeated collisions has profound implications for our understanding of the universe. Further studies of the Pandora’s Cluster, the most complex and fascinating merger yet found, are in progress.