he Milky Way Galaxy has acquired a collection of high-velocity hydrogen clouds by stealing gas from smaller galaxies.
May 14, 2003
May 14, 2003
Hydrogen maps of the Magellanic Clouds (the two white spots to the left) show streams of material trailing behind the galaxies. Called the Magellanic Stream, this material was stripped off the two small galaxies by our Milky Way.
Photo by M. Putman (U. Colorado)/L. Staveley-Smith (CSIRO)/K. Freeman (ANU)/B. Gibson, D. Barnes (Swinburne)
Forty years ago astronomers discovered clouds of hydrogen gas moving with high velocities near the Milky Way Galaxy. It had been unclear, until now, if these clouds were gravitationally bound to the Milky Way or were simply passing near our galaxy as they traveled through the Local Group. Recent studies presented by Mary Putman of the University of Colorado show that these clouds are probably material stripped from small galaxies and that they are now companions of the Milky Way.
Using the Commonwealth Scientific and Industrial Research Organisation's Parkes Radio Telescope in eastern Australia, Putman and her collaborators made highly detailed maps of hydrogen gas in and near the orbital paths of the Magellanic Clouds. Along the orbits of these two galaxies is a trail of material — including hydrogen gas — called the Magellanic Stream. Our galaxy ripped this material from the Magellanic Clouds. Putman and her team believe the high-velocity clouds have similarly destructive origins and were created when the Milky Way looted material from additional small galaxies.
It's also possible that the clouds were created by some sort of a fountain of material from our Milky Way or via interaction with the Magellanic Clouds. Whatever their origins, the high velocity clouds are local to our galaxy.
As shown in this illustration, gas stripped from the Magellanic Clouds follows in front and behind the two galaxies.
Photo by Daisuke Kawata, Chris Fluke, Sarah Maddison, Brad Gibson (Swinburne University of Technology)
"We now have pretty conclusive evidence that the high-velocity clouds are not scattered throughout our Local Group of galaxies, but are within the extended halo of the Milky Way," says Putman.
These results fit well with related observations of other groups of galaxies. "Previous studies of other galaxy groups haven't found any counterparts of the high-velocity clouds," said team member Lister Staveley-Smith of the Australia Telescope National Facility. "If the clouds are there, they must lie close to the big galaxies rather than scattered throughout galaxy groups." If large galaxies create the clouds by stripping material from small, nearby galaxies, the clouds will naturally lay close to large galaxies.
This has important implications for the dark-matter distribution in groups of galaxies like our own Local Group. Some galaxy formation models predict that there are small lumps or "halos" of cold dark matter scattered throughout the Local Group. Astronomers wondered whether high-velocity clouds represented these otherwise-invisible halos of dark matter.
The 64-meter Parkes Radio Telescope was built in 1961. It is located near Alectown, 25 kilometers (16 miles) north of the town of Parkes, which is approximately 365 kilometers (227 miles) west of Sydney.
Photo by CSIRO
If the high-velocity clouds traced the locations of these dark matter halos, you'd expect the clouds to be strewn throughout the Local Group. But because the gas clouds are only found close to the Milky Way they cannot be associated with the dark matter halos. While dark matter halos may still roam the Local Group, they aren't associated with these streaming clouds of hydrogen.