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News Release

Office of News and Information
Johns Hopkins University
3400 N. Charles Street
Baltimore, Maryland 21218-2692
Phone: (410) 516-7160
Fax (410) 516-5251

March 12, 1998
FOR IMMEDIATE RELEASE
SCIENCE CONTACT: Dr. Arjun Dey
dey@pha.jhu.edu / (410) 516-4345
MEDIA CONTACT: Emil Venere
Emil@jhu.edu

Discovery Pushes Back Boundaries of Known Universe

Astronomers using the largest optical and infrared telescopes in the world have found the most distant known object in the cosmos, a young galaxy in existence when the universe was only 6 percent of its present age, and nearly 90 million light-years farther than any previously discovered.

The serendipitous discovery is raising realistic hopes that the emerging generation of large ground-based telescopes will unveil the formative stages of galaxies, allowing astronomers to resolve two of the central questions facing contemporary astrophysics: How and when did galaxies form?

The findings will be detailed in a scientific paper to be published in an upcoming issue of the Astrophysical Journal Letters. The paper was written by Arjun Dey, a Hubble Postdoctoral Fellow at The Johns Hopkins University, astronomers Hyron Spinrad, Daniel Stern and James R. Graham at the University of California, Berkeley, and Frederic H. Chaffee at the W.M. Keck Observatory in Hawaii.

"It is an extremely exciting discovery, since so little is known about this stage of the universe, in terms of the objects that lived there, or how galaxies -- giant collections of stars -- might form," Dey said.

"We are trying to find baby galaxies. These are galaxies that would eventually turn into something like the one we live in, but would be undergoing their first episode of star formation. In other words ... they are essentially collapsing from a large gas cloud and forming their first generation of stars."

Because of its great distance and the constant speed of light, astronomers now see the galaxy as it was when the universe was only 6 percent of its present age, about 820 million years after the Big Bang. Astrophysicists need to observe embryonic galaxies to test, refine and/or refute theories about how galaxies form. Without direct, observational evidence, specific theories cannot be substantiated.

"The problem is that, although people have looked for many, many years, they have never been able to find galaxies that are truly primeval," said Dey.

Astronomers don't yet know whether they have now discovered one such primeval galaxy, but it is their best candidate to date. Scientists can determine the distance to a galaxy by measuring the speed with which it is moving away from us as the universe expands. More distant galaxies are receding faster, a phenomenon observed in the late 1920s by American astronomer Edwin Hubble. The faster a galaxy is moving, the more its light is shifted to the longer (or redder) wavelengths. The light is said to be "red shifted."

The farther away a galaxy is, the faster it appears to be receding from us, and the greater its redshift. The newly discovered galaxy, called 0140+326RD1 (or RD1), has a redshift of 5.34, marking the first time the 5.0 redshift barrier has been broken.

"We've never had any glimpse of what might be at redshifts beyond 5," said Dey, the team leader. "But now that we know what to look for, I'm sure this record will be broken in a matter of months."

The astronomers discovered RD1 while they were observing distant galaxies with the 10-meter Keck II Telescope located atop Mauna Kea, a dormant volcano on the Big Island of Hawaii. Keck II is an identical twin to the 10-meter Keck I; they are the largest optical and infrared telescopes in the world. In September 1997, Dey, Spinrad, Stern and Graham were using the Keck Low-Resolution Imaging Spectrograph to analyze the light from a very distant and faint galaxy in the constellation of Triangulum, when they spotted something unexpected: the spectral signature of another even fainter galaxy which had not been seen on existing images of that patch of sky.

In December, the team took deeper images by increasing the exposure time of their observations. "And sure enough, we began to see something show up: a faint blob," Dey said. Keck Observatory director Frederic Chaffee joined the team, and they studied the object's light again, confirming the discovery of the new, extremely distant galaxy. The astronomers are continuing follow-up observations with Keck, and they hope to observe the object with the Hubble Space Telescope.

"Astronomers the world over have spent years devising clever techniques to find galaxies beyond redshift 5, but so far have come up empty," said Chaffee, who has watched numerous teams search for such ultra-distant objects. "We had assumed this was because such objects are extremely rare and faint -- rather like seeking out the needle in a 10,000,000-straw haystack. But here, one was found serendipitously by observing only one tiny area of sky."

The previous most-distant known object was a galaxy at redshift 4.92, discovered by astronomers using the Keck and Hubble telescopes.

"How galaxies formed in the early universe is one of the most exciting puzzles in astronomy today," said Hugh Van Horn, director of the National Science Foundation's Division of Astronomical Sciences. "This record-breaking observation will give us new information about a galaxy in its youth."

The actual age of the universe is a matter of debate. However, if astronomers use 13 billion years as the age of the universe, then light from RD1 was emitted when the universe was 820 million years old. The light has traveled a distance of about 12.22 billion light-years. The previous most-distant galaxy is about 12.13 billion light-years from Earth, nearly 90 million light-years closer than RD1.

RD1 is a fairly average galaxy, with a mass and luminosity less than that of the Milky Way, Dey said. That finding gives astronomers hope that the embryonic stages of galaxies similar to today's large spiral and elliptical galaxies might be bright enough to be seen with greater ease by the Kecks and other large telescopes now being built.

Presently, the two 10-meter Keck telescopes are unrivaled. But within a decade, about a dozen 8-meter class telescopes will join the hunt for answers to some of the most pressing questions facing cosmology today.

"We are sort of at a watershed in observational cosmology, in terms of understanding how galaxies form and evolve," Dey said.

The astronomers hope to find other primeval galaxy candidates at even larger distances. "Deep targeted searches with the new generation of large ground-based telescopes will soon uncover more nascent galaxies," said Spinrad.

The Hopkins/UC-Berkeley/Keck research has been funded by NASA and the National Science Foundation.

Note: An image showing the area of the sky containing the galaxy can be downloaded at the following Web address: http://www.jhu.edu/news_info/news/home98/mar98/images/stellar.gif

A print of the image also is available by contacting Emil Venere at the phone number and e-mail address listed at the top of this release. Other media contacts for this story are Bob Sanders, at UC-Berkeley, (510) 643-6998, (rls@pa2.urel.berkeley.edu), and Andrew Perala, at the W.M. Keck Observatory, (808) 885-7887 ( aperala@keck.hawaii.edu).


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