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                              3 p.m EDT September 4 1996,

 CONTACT:  Don Savage
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       (Phone: 602/965-3502)


RELEASE:  96-XXX

HUBBLE SEES EARLY BUILDING BLOCKS OF TODAY'S GALAXIES 

New Hubble Space Telescope HST images reveal what may be a galaxy under
construction in the early universe, out of a long sought ancient population of
"galactic building blocks." 

Hubble's detailed images, taken with the Wide Field Planetary Camera 2,  reveal
a grouping of 18 gigantic star clusters that appear to be the same distance from
Earth, and close enough to each other that they will eventually merge into a
single, galaxy-sized object. They are so far away, 11 billion light-years, that
they existed during the epoch when it is commonly believed galaxies started to
form. 

These results add weight to a leading theory that galaxies grew through
"corporate mergers," starting out as clumps of stars, which, through a complex
series of encounters, consolidated into larger assemblages that we see as
fully-formed galaxies today. 

The finding is another step back into the dim past, where astronomers ultimately
hope to uncover the earliest seeds of galaxy formation which arose shortly after
the birth of the universe, or the Big Bang. 

Astronomers at Arizona State University, Tempe, AZ, (ASU) and the University of
Alabama at Tuscaloosa found 18 of these cosmic building blocks packed into an
area about two-million light years across.  "It's the first time anyone has seen
that many star-forming objects in such a small space. There are not nearly as
many such luminous objects in the two-million light years separating Earth's
galaxy, the Milky Way, from the Andromeda Nebula, the nearest major galaxy",
says Rogier Windhorst of Arizona State University. 

The astronomers will publish their findings in an article, authored by ASU
graduate student Sam Pascarelle, in the Sept. 5 issue of the journal Nature. The
coauthors are ASU's Rogier Windhorst and Stephen Odewahn, and William Keel of
the University of Alabama at Tuscaloosa. 

The building blocks seen by Hubble consists of only about a billion young stars
each, and Hubble shows star formation is underway through the presence of many
blue stars and glowing gases.  The objects typically measure only 2,000 light
years across. "That's not very big. Our own galaxy is 100,000 light years
across," Odewahn says.  The objects are much smaller than even the central bulge
of the Milky Way, which measures about 8,000 light years in diameter.  "We think
that by repeated merging, they will grow big enough to become the bulges of
nearby galaxies," says Keel, citing other HST studies that have shown that the
galaxy merger or collision rate was higher in the past. "In fact, at least four
of the objects in this field show double structure in their centers only a few
thousand light-years apart, as if we've caught them in the act of falling
together." 

Hubble shows a new level of detail for determining the true nature of these
"pre-galactic blobs." Hubble resolved clumps as small as 2,000 light-years
across (1/10th of an arc second). These were seen in a two-day (67-orbit)
exposure by Hubble of a small region of sky in the northern part of the Hercules
constellation near the border with Draco. 

"We've never seen so many of these objects in a single exposure and so small,"
says Pascarelle. "But we are convinced that these objects are not peculiar, but
part of the general formation process of galaxies in the early universe." 

Astronomers see stars form, because star formation is an ongoing process.
However, astronomers have never directly seen galaxies form, because formation
may have happened a long time ago, or because galaxy formation as spectacular as
once believed, and therefore much harder to observe. 

The idea that galaxies grew from small pieces coming together, rather than
through the collapse of a gigantic gas cloud, has been predicted from previous
theoretical work and ground-based observations.  The Hubble observations offer
some of the best direct visual evidence to date, says Pascarelle. 

Though many of the objects are isolated in the image, they are close enough
together in space that most of them should eventually merge, according to
Windhorst. He sketches a scenario where two or more objects will pass through
each other (although the term "collision" is used, their individual stars don't
collide), drawing out hydrogen gas to form more stars later. They may then
evolve to form the numerous faint blue galaxies, a distant population of
galaxies seen by Hubble and other telescopes. Later, surrounding hydrogen gas
then settles into a disk to form a spiral galaxy. 

If this construction plan is correct, our Milky Way galaxy contains all the
pieces of the assembly process. The older, redder stars in the Milky Way's
central bulge came from the merged clusters, or "sub-galactic units," seen by
Pascarelle and collaborators. The spiral arm that our Sun inhabits was made
later after hydrogen settled into a disk. Some of the 140 globular star clusters
which orbit the Milky Way may be "left over" smaller building blocks which
formed before the larger units seen by Pascarelle and collaborators, but were
never pulled directly into larger assemblages. 

In some of the deepest exposures of the universe (apart from the Hubble Deep
Field) yet obtained by the telescope, the astronomers found 18 objects in one
image, in the vicinity of a faint radio galaxy they were studying.  The
researchers used an optical filter precisely tuned to detect the ultraviolet
emission from glowing hydrogen gas heated by newborn stars that formed early in
the universe, but shifted to longer visual wavelengths by the universal
expansion.  "This is a case where Hubble is uniquely suited to study
sub-galactic objects at these great distances," says Windhorst, "because these
objects are so compact that it would be very hard to recognize them from the
ground". 

Follow-up spectroscopic observations with the Multi-Mirror Telescope at Mt.
Hopkins, Arizona (MMT) showed at least five of the clumps are all at the same
distance from Earth.  The team confirmed that another five objects were at the
same distance by imaging another redshifted hydrogen line in the near infrared
with NASA's Infrared Telescope Facility, and through spectroscopic follow-up at
the 10 meter W. M. Keck Telescope, both on Mauna Kea, Hawaii (the latter by Drs.
Nicholas Scoville and Lee Armus of Caltech). 

The amount of redshift corresponds to a distance of 11 billion light years --
far enough to probe the early universe during the period where many of the giant
galaxies were being assembled. The astronomers were surprised to find so many
small objects at the same distance that were so close together and also very
blue, indicating new star formation. 

In a companion paper in press for the Astrophysical Journal Letters, Stephen
Odewahn, Windhorst, Keel, and Simon Driver (from the University of New South
Wales in Sydney, Australia) show that the counts of faint blue objects in this
field are no different from that in other deep HST fields. Astronomers interpret
this to mean that in almost every direction an observer should see similar
activity going on at these distances -- the gradual construction of galaxies
from faint blue sub-galactic building blocks. 

                               -end- 

                        SCIENCE BACKGROUNDER 

            GALAXY BUILDING BLOCK AND COLD DARK MATTER THEORIES 

The Hubble images of sub-galactic objects which may be merging show exactly what
the so-called `cold dark matter' theory for the evolution of cosmic structures
predicts, say the researchers. The dark matter theory tries to explain why 90
percent of the matter in the universe is invisible to telescopes. Astronomers
theorize the existence of dark matter from the gravitational effects it exerts
on the galaxies it surrounds. 

Cold dark matter could be as simple as rocks, or as exotic as cosmic particles
such as neutrinos, or some other unkown particle. Whatever it is, there is a
lot of it.  "Since dark matter has mass, it has gravity, and therefore it
affects this entire scenario of forming clumps and forming bigger clumps,"
Windhorst said. "These halos of cold dark matter help form galaxies." 

If the dark matter is ``cold,'' meaning that its random motions are much slower
than the speed of light, it tends to form structure from the bottom up. That is,
the smallest clumps of stars (star clusters and small galaxies) formed first,
then merged together to form larger galaxies like our own Milky Way. These
galaxies, in turn, then grouped together into clusters or superclusters giving
us the highly fragmented and filamentary structure that we see in the universe
today. 

In contrast, if the dark matter is ``hot,'' i.e. made up of particles, such as
neutrinos, that move at nearly the speed of light, then only the largest
structures can condense in the early universe. Smaller structures such as
galaxies and star clusters must have formed later, from fragments within these
larger structures. 

"Neither scenario can be completely correct, strictly speaking, because we know
that these sub-galactic objects already existed a very long time ago. They're
very old, and therefore they must have formed shortly after the Big Bang,"
Windhorst says. "Also, some structure on the scales of superclusters may have
condensed out of the primeval soup as shortly as one million years after the
Big-Bang." 

He concludes: "Perhaps a hybrid model is necessary, but mostly leaning toward
the cold dark matter. This idea that small clumps grow into bigger ones is very
effective. It explains a lot of things, but it doesn't quite explain the
existence of large scale structures early on." 

In fact, Pascarelle and his colleagues suggest that their tightly packed group
of faint blue sub-galactic building blocks are themselves part of such an early,
large-scale structure. "One wonders if we simply got lucky, that we looked at an
unusual patch of sky, and that these objects are not a regular part of the
large-scale structure of the Universe," says Pascarelle. But this concern would
be relieved if the Hubble Telescope reveals a similar crowding of objects in
other parts of the sky at similar large distances. Some hints for that are now
being seen in other parts of the sky. The team has further Hubble observations
scheduled for other fields in the sky, to see whether in fact these small
objects at such large distances are the rule, rather than the exception. "That
would show that this kind of structure exists throughout the universe, and
confirm our hypothesis that most galaxies may have formed through the mergers of
smaller clumps" Pascarelle says. 


                               -end- 


EDITOR'S NOTE: Images to accompany this release are available
from the NASA Headquarters Imaging Branch by calling
202/358-1900.  Photo numbers are: 
          Color          B&W
          96-HC-XXX 96-H-XXX

The images also are available electronically through the Internet
via World Wide Web, ftp or Gopher.  The Internet addresses are:  
ftp:      ftp.stsci.edu  (IP address:  130.167.1.2)    
WWW URL: http://www.stsci.edu
Gopher:        www.stsci.edu

                        >end of release<