15 April 2015

Dark Matter Interactions Observed in Galaxy Collision at Abell 3827

While studying the simultaneous collision of four galaxies in the galaxy cluster Abell 3827, the European Southern Observatory's VLT and NASA/ESA's Hubble Space Telescope may have, for the first time, observed dark matter interactions with other dark matter.

The nature of dark matter is still a mystery but it is believed that it comprises 85% of the Universe’s mass; the rest being "normal matter". Without dark matter, galaxies would not be able to hold itself together and would fling themselves apart while they rotate. Dark matter keeps these galaxies together due to the constraining effect of its' gravity.

Researches observed that during the collision, one clump of dark matter appeared to be lagging behind the galaxy it surrounds. The dark matter is currently 5000 light-years behind the galaxy.

Dark matter has always been observed interacting with gravity but the computer simulation of the four galaxy collision at Abell 3827 show that extra friction from the collision would slow down dark matter and that the nature of that interaction is not gravity and still is unknown. It is also uncertain how long it took for the collision to happen.The friction that slowed the dark matter could have been a very weak force acting over about a billion years, or a relatively stronger force acting for “only” 100 million years.

Dark Matter Interactions

For the first time dark matter may have been observed interacting with other dark matter in a way other than through the force of gravity. Observations of colliding galaxies made with ESO’s Very Large Telescope and the NASA/ESA Hubble Space Telescope have picked up the first intriguing hints about the nature of this mysterious component of the Universe.

Using the MUSE instrument on ESO’s VLT in Chile, along with images from Hubble in orbit, a team of astronomers studied the simultaneous collision of four galaxies in the galaxy cluster Abell 3827. The team could trace out where the mass lies within the system and compare the distribution of the dark matter with the positions of the luminous galaxies.

Although dark matter cannot be seen, the team could deduce its location using a technique called gravitational lensing. The collision happened to take place directly in front of a much more distant, unrelated source. The mass of dark matter around the colliding galaxies severely distorted spacetime, deviating the path of light rays coming from the distant background galaxy — and distorting its image into characteristic arc shapes.


Our current understanding is that all galaxies exist inside clumps of dark matter. Without the constraining effect of dark matter’s gravity, galaxies like the Milky Way would fling themselves apart as they rotate. In order to prevent this, 85 percent of the Universe’s mass must exist as dark matter, and yet its true nature remains a mystery.

In this study, the researchers observed the four colliding galaxies and found that one dark matter clump appeared to be lagging behind the galaxy it surrounds. The dark matter is currently 5000 light-years (50 000 million million kilometres) behind the galaxy — it would take NASA’s Voyager spacecraft 90 million years to travel that far.

A lag between dark matter and its associated galaxy is predicted during collisions if dark matter interacts with itself, even very slightly, through forces other than gravity. Dark matter has never before been observed interacting in any way other than through the force of gravity.

Lead author Richard Massey at Durham University, explains: “We used to think that dark matter just sits around, minding its own business, except for its gravitational pull. But if dark matter were being slowed down during this collision, it could be the first evidence for rich physics in the dark sector — the hidden Universe all around us.”

The researchers note that more investigation will be needed into other effects that could also produce a lag. Similar observations of more galaxies, and computer simulations of galaxy collisions will need to be made.

Team member Liliya Williams of the University of Minnesota adds: “We know that dark matter exists because of the way that it interacts gravitationally, helping to shape the Universe, but we still know embarrassingly little about what dark matter actually is. Our observation suggests that dark matter might interact with forces other than gravity, meaning we could rule out some key theories about what dark matter might be.”

This result follows on from a recent result from the team which observed 72 collisions between galaxy clusters and found that dark matter interacts very little with itself. The new work however concerns the motion of individual galaxies, rather than clusters of galaxies. Researchers say that the collision between these galaxies could have lasted longer than the collisions observed in the previous study — allowing the effects of even a tiny frictional force to build up over time and create a measurable lag.

Taken together, the two results bracket the behaviour of dark matter for the first time. Dark matter interacts more than this, but less than that. Massey added: “We are finally homing in on dark matter from above and below — squeezing our knowledge from two directions.”


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Baryon Oscillation Spectroscopic Survey (BOSS) Studying and Observing the Accelerating and Expanding Universe
Dark Energy May Explain How The Universe Will End
Baryon Oscillation Spectroscopic Survey (BOSS) Publicly Release Data On More Than 750,000 Galaxies, Quasars, and Stars