From: Andrew Yee <ayee@nova.astro.utoronto.ca>
Newsgroups: sci.space.news
Subject: 'Red dots' may re-write the history of the universe (Forwarded)
Date: Thu, 28 Dec 2000 13:20:43 -0500
Organization: Jet Propulsion Laboratory - Pasadena CA
Approved: sci-space-news@zagami.jpl.nasa.gov
Message-ID: <3A4B847C.33C672E9@nova.astro.utoronto.ca>
Reply-To: ayee@nova.astro.utoronto.ca

Commonwealth Scientific and
  Industrial Research Organisation
Australia

Contacts:

Ms Helen Sim
Sector Communicator
Australia Telescope National Facility
PO Box 76
Marsfield NSW 1710
Phone: +61 2 9372 4251
Fax: +61 2 9372 4310
Email: hsim@atnf.csiro.au

Ms Rosie Schmedding
Communicator
CSIRO National Awareness
PO Box 225
Dickson ACT 2602
Phone:+61 2 6276 6520
Fax:+61 2 6276 6821
Mobile: +61 0418 622 653
Email: Rosie.Schmedding@nap.csiro.au

'Red dots' may re-write the history of the universe

Media Release: Thursday, 28 December 2000		Ref 2000/341

The earliest stars of the Universe may be much older than previously
thought following the discovery of the strongest evidence for an entirely
new kind of galaxy by scientists using CSIRO's Australia Telescope and the
Hubble Space Telescope.

"We think they are galaxies that are absolutely fizzing with star
formation -- a sort of huge stellar baby-boom," says CSIRO's Professor
Ray Norris, leader of the Australia Telescope observing team.

"They seem to be a hundred times more active than even the most frenzied
star-forming galaxy in today's Universe -- the kind of galaxy we call
'starburst'," he says.

Many of these galaxies must be very faint. They might be very common, even
outnumbering all the distant galaxies that astronomers had seen before.

"If that's the case, it pushes back the epoch of maximum star formation --
when the Universe really got active -- by a long way," Professor Norris
says.

"The Australia Telescope observations have unearthed a source that may be
a key to understanding how galaxies began to form," says Dr Bob Williams,
the former Director of the Space Telescope Science Institute who initiated
the Hubble Deep Field observing campaigns.

"If the strange source the Australia Telescope has found is an early
starburst galaxy, then we now have solid evidence for what may have been
a brief and furious burst of star formation activity in some unique
galaxies -- possibly the first really large structures that formed in
the universe," he says.

"For astronomers, this is like pushing back the date at which people
arrived in Australia, or the date at which life started on Earth," comments
Dr Brian Boyle, Director of the Anglo-Australian Observatory, which helped
to select the region of sky to be observed.

Professor Norris says that because light takes a finite time to travel,
'far away' in space equals 'long ago'. When looking deep into space
astronomers are looking back into the history of the Universe and seeing
galaxies that no longer exist.

The Hubble Space Telescope (HST) made its first deep scrutiny of the
Universe in 1993. In a tiny patch of the northern sky it picked out
galaxies that existed when the Universe was only a tenth of its present
age.

In 1998 the HST's keen eye was turned on a patch of the southern sky,
called the Hubble Deep Field South. The exact patch to be viewed was
determined joint observations by the Anglo-Australian Telescope,
Australia's largest optical telescope, and CSIRO's Australia Telescope,
the most advanced radio telescope in the Southern Hemisphere. The HST
and the Australia Telescope then examined the area in detail.

The radio telescope observations show that a faint red dot in the Hubble
field, dubbed 'source c', is a very unusual object.

The colours of its light suggest that it lies between five and eleven
billion light-years away.

"That in itself is not remarkable," says Professor Norris. "But this
galaxy is the most extreme example of a class of objects in the Hubble
fields which are very faint in visible light but quite bright at radio
wavelengths".

For now, astronomers are stuck with a mystery. But the next generation of
telescopes will help them clear up the tantalizing questions so far raised
about the early Universe, says Dr Norris.

"Even the world's largest telescope, the Very Large Telescope in Chile,
can't collect enough light from this object to really pin down its
distance. That will probably have to wait for optical telescopes now on
the drawing board -- ones with mirrors 30 m across or even bigger."

The first of these giant light buckets, the California Extremely Large
Telescope, may be built in the next few years.

Astronomers are also looking forward to a 'mega-collector' radio telescope,
the Square Kilometre Array, due for construction around 2010. This may be
built in Australia.

"The Square Kilometre Array will be able to detect galaxies like 'source c'
at great distances. It could tell us just how common these objects are in
the early Universe," says Professor Norris.

IMAGE CAPTIONS:

[Image 1:
http://www.csiro.au/page.asp?type=imageDef&id=Australia_Telescopelarge]
Two antennas of CSIRO's Australia Telescope Compact Array near Narrabri,
NSW. Photo: S. Duff, CSIRO

[Image 2: http://www.csiro.au/page.asp?type=imageDef&id=HDFS_objectlge]
The faint red galaxy (marked) in the Hubble Deep Field South, a region of
the southern sky imaged by the Hubble Space Telescope. Credit: R. Williams
(STScI), the HDF-S Team, and NASA. For more about the Hubble Deep Field
South, go to http://oposite.stsci.edu/pubinfo/pr/1998/41/

[Image 3: http://www.csiro.au/page.asp?type=imageDef&id=HST]
The Hubble Space Telescope (HST). Australia's west coast can be seen in
the background. Credit: NASA

More information:

Professor Ray Norris
Deputy Director, Australia Telescope National Facility
02-9372-4416, 0417-288-307
rnorris@atnf.csiro.au

Dr Brian Boyle
Director, Anglo-Australian Observatory
02-6842-6279, (Anglo-Australian Telescope - afternoon only)
director@aaoepp.aao.gov.au

Ms Helen Sim
02-9372-4251
Helen.Sim@atnf.csiro.au


-- 
Andrew Yee
ayee@nova.astro.utoronto.ca