Astronomers Discover a River of Stars Streaming Across the NorthernSky (Forwarded)

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March 15, 2006

Astronomers Discover a River of Stars Streaming Across the Northern Sky

PASADENA, Calif. -- Astronomers have discovered a narrow stream of stars
extending at least 45 degrees across the northern sky. The stream is
about 76,000 light-years distant from Earth and forms a giant arc over
the disk of the Milky Way galaxy.

In the March issue of the Astrophysical Journal Letters, Carl Grillmair,
an associate research scientist at the California Institute of
Technology's Spitzer Science Center, and Roberta Johnson, a graduate
student at California State University Long Beach, report on the discovery.

"We were blown away by just how long this thing is," says Grillmair. "As
one end of the stream clears the horizon this evening, the other will
already be halfway up the sky."

The stream begins just south of the bowl of the Big Dipper and continues
in an almost straight line to a point about 12 degrees east of the
bright star Arcturus in the constellation Bootes. The stream emanates
from a cluster of about 50,000 stars known as NGC 5466.

The newly discovered stream extends both ahead and behind NGC 5466 in
its orbit around the galaxy. This is due to a process called tidal
stripping, which results when the force of the Milky Way's gravity is
markedly different from one side of the cluster to the other. This tends
to stretch the cluster, which is normally almost spherical, along a line
pointing towards the galactic center.

At some point, particularly when its orbit takes it close to the
galactic center, the cluster can no longer hang onto its most outlying
stars, and these stars drift off into orbits of their own. The lost
stars that find themselves between the cluster and the galactic center
begin to move slowly ahead of the cluster in its orbit, while the stars
that drift outwards, away from the galactic center, fall slowly behind.

Ocean tides are caused by exactly the same phenomenon, though in this
case it's the difference in the moon's gravity from one side of Earth to
the other that stretches the oceans. If the gravity at the surface of
Earth were very much weaker, then the oceans would be pulled from the
planet, just like the stars in NGC 5466's stream.

Despite its size, the stream has never previously been seen because it
is so completely overwhelmed by the vast sea of foreground stars that
make up the disk of the Milky Way. Grillmair and Johnson found the
stream by examining the colors and brightnesses of more than nine
million stars in the Sloan Digital Sky Survey public database.

"It turns out that, because they were all born at the same time and are
situated at roughly the same distance, the stars in globular clusters
have a fairly unique signature when you look at how their colors and
brightnesses are distributed," says Grillmair.

Using a technique called matched filtering, Grillmair and Johnson
assigned to each star a probability that it might once have belonged to
NGC 5466. By looking at the distribution of these probabilities across
the sky, "the stream just sort of reached out and smacked us.

"The new stream may be even longer than we know, as we are limited at
the southern end by the extent of the currently available data," he
adds. "Larger surveys in the future should be able to extend the known
length of the stream substantially, possibly even right around the whole
sky."

The stars that make up the stream are much too faint to be seen by the
unaided human eye. Owing to the vast distances involved, they are about
three million times fainter than even the faintest stars that we can see
on a clear night.

Grillmair says that such discoveries are important for our understanding
of what makes up the Milky Way galaxy. Like earthbound rivers, such
tidal streams can tell us which way is "down," how steep is the slope,
and where the mountains and valleys are located.

By measuring the positions and velocities of the stars in these streams,
astronomers hope to determine how much Dark Matter the Milky Way
contains, and whether the dark matter is distributed smoothly, or in
enormous orbiting chunks.

[NOTE: An image supporting this release is available at
http://spider.ipac.caltech.edu/staff...OfStars_R2.jpg
(645KB)]