A vast, thin plane of corotating dwarf galaxies orbiting Andromeda
3 January 2013
A newly discovered form of coplanar dwarf galaxy structure is challenging astronomers; not due to their complex orbits, but they present a challenge to our ideas of how all galaxies form and evolve. The finding was published in the prestigious journal Nature on 3 January 2013.
The international group of astronomers including Professor Geraint Lewis from the University of Sydney's School of Physics, and Australian astronomers Anthony Conn, a PhD student at Macquarie University, and Dr Dougal Mackey from the Australian National University, are surprised at the circle around Andromeda that the small orbiting galaxies have formed.
The research result reveals that around half of Andromeda's 30-odd known dwarf galaxy satellites are orbiting the larger Andromeda Galaxy - the closest giant cosmic neighbour to our own galaxy, the Milky Way.
"Astronomers have been observing Andromeda since Persian astronomers first noted it over a thousand years ago, but it is only in the past decade that we have truly studied it in exquisite detail with the Pan-Andromeda Archaeological Survey," said Professor Geraint Lewis, one of the lead authors on the Nature paper.
"The Pan-Andromeda Archaeological Survey, PAndAS, is a large project that ran between 2008 and 2011, using the Canada-France-Hawaii Telescope situated on the Mauna Kea volcano on the Big Island of Hawaii. Now that we're examining the data it collected, it is providing our first panoramic view of our closest large companion in the cosmos," explained Professor Lewis.
By making distance measurements of the dwarf galaxies from their host Andromeda, the astronomers have been able to construct a picture of not only the position of these dwarf galaxies from an Andromeda point of view, but also their radial velocity around the host galaxy.
"When we looked at the dwarf galaxies surrounding Andromeda, we expected to find them buzzing around randomly, like angry bees around a hive. Instead, we've found that half of Andromeda's satellites are orbiting together in an immense plane, which is more than a million light years in diameter but only 30 000 light years thick. These dwarf galaxies have formed a ring around Andromeda."
"This was completely unexpected - the chance of this happening randomly is next to nothing. It really is just weird," said Professor Lewis.
Large galaxies, like Andromeda and our own Milky Way, have long been known to be orbited by an entourage of smaller galaxies. These dwarf galaxies, which can be individually up to at least hundreds of thousands of times fainter than their bright hosts, were thought to follow an independent orbit around their hosts.
For several decades, astronomers have used computer models to predict how dwarf galaxies should orbit large galaxies, finding that dwarfs should be scattered randomly over the sky. Never, in these models, did they see dwarfs arranged in a plane like that observed around Andromeda.
"Now that we've found that the majority of these dwarf galaxies orbit in a disc around the giant galaxy Andromeda, it looks like there must be something about how these galaxies formed or subsequently evolved that has led them to trace out this peculiar coherent structure," said Professor Lewis.
"Dwarf galaxies are the most numerous galaxy type in the universe, so understanding why and how they form this disc around the giant galaxy is expected to shed new light on the formation of galaxies of all masses."
PhD student, Anthony Conn, whose research proved key to this study said, "It is very exciting for my work to reveal such a strange structure. It has left us scratching our heads as to what it means."
There have been similar claims of an extensive plane of dwarf galaxies about our own Milky Way Galaxy, with some claiming that the existence of such strange structures points to a failing in our understanding of the fundamental nature of the Universe.
"We don't yet know where this is pointing us, but it surely is very exciting," said Dr Rodrigo Ibata, from the Observatoire astronomique de Strasbourg, in France, and lead author on the report.Read the paper in Nature at: www.nature.com/nature/journal/v493/n7430/full/nature11717.html?WT.ec_id=NATURE-20130103
Contact: Tom Gordon
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