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Contact: Diane Ainsworth

FOR IMMEDIATE RELEASE                       October 26, 1994

     Observations of a remote galaxy in the Virgo cluster by 
the Jet Propulsion Laboratory's Wide Field and Planetary 
Camera-2 -- on board NASA's Hubble Space Telescope -- have 
yielded the most accurate estimate yet of the distance to 
that galaxy and the rate at which the universe is expanding.
  
     Images of Messier 100, a large spiral galaxy in the 
constellation Virgo, revealed bright Cepheid stars which 
were used to pinpoint the galaxy's distance at approximately 
51 million light-years from Earth.  The observations mark 
the completion of a major milestone for the recently 
refurbished Hubble telescope, designed to measure distant 
galaxies and determine the true value of the Hubble 
constant, first demonstrated in 1929 by the American 
astronomer Edwin Hubble.
 
     The findings were presented in this week's issue of 
Nature in an article entitled, "Distance to the Virgo 
Cluster Galaxy M100 from Hubble Space Telescope Observations 
of Cepheid Variables."  An international team of 
astronomers, led by Dr. Wendy L. Freedman of the Carnegie 
Observatories in Pasadena, Calif. and Dr. Barry Madore of 
the California Institute of Technology/JPL Infrared 
Processing and Analysis Center (IPAC), coauthored the paper.
 
     "Although this is only the first step in a major 
systematic program to securely measure the dimensions and 
age of the universe, a firm distance to the Virgo cluster is 
a critical milestone for the extragalactic distance scale," 
Freedman said.  "This accomplishment has major implications 
for our determination and understanding of the Hubble 
constant."

     Freedman and her colleagues made the determination 
during a 60-day observing window which began in April 1994 
and ended in June 1994.  Other members of the science team 
included Drs. Robert Kennicutt of Steward Observatory, 
University of Arizona and Jeremy Mould of Mount Stromlo and 
Siding Springs Observatories at the Australian National 
University.
 
     The team used JPL's Wide Field and Planetary Camera-2 
to image a field of stars set off from the nucleus of M100 
but, nevertheless, including regions rich in recent star 
formation and potential Cepheid candidates.  

     Cepheids are pulsating, very luminous, supergiant stars 
that regularly dim and brighten in a characteristic "saw 
tooth" pattern of light variation.  Periods range from a few 
days to a few hundred days.  

     Astronomers have known for more than half a century 
that the period of variation in a Cepheid precisely predicts 
its total luminosity.  By comparing the predicted brightness 
with the observed brightness, they are able to calculate 
distances in the universe.

     "Only the orbiting Hubble Space Telescope can make 
these types of observations routinely," Freedman said.  
"Typically, Cepheids are too faint and the resolution is too 
poor as seen from ground-based telescopes to clearly detect 
them in a crowded region of a distant galaxy."

     Twelve one-hour exposures, strategically timed within 
the two-month observing window, did, in fact, result in the 
discovery of 20 new Cepheids and the simultaneous 
determination of periods and measurements of average 
brightness.  

     More than 40,000 stars were measured in the search for 
these rare but bright variables, said Dr. Barry Madore of  
NASA's Infrared Processing and Analysis Center at Caltech.  
Once identified, intermittent observations made at near-
infrared wavelengths were able to account for the dimming 
effects caused by dust and gas found along Hubble's line of 
sight out of the Milky Way galaxy and into the Virgo galaxy.

     The target galaxy, M100, is a large, face-on rotating 
system of gas and stars similar to the Milky Way galaxy in 
which the solar system resides.  This galaxy has been host 
to several massive star explosions, called supernova, which 
are considered significant distance indicators among 
astronomers and cosmologists.  Agreement between the Cepheid 
star distances and M100's supernova distances adds 
significant weight to the astronomers' new calculations of 
the Hubble constant.

     "Now that we've got an accurate measurement of a galaxy 
in the Virgo cluster, we will begin to observe other, more 
distant galaxies and get a handle on other Cepheid 
distances," Madore said.  "This is an objective that was 
nothing more than a wish and a dream to astronomers five 
years ago."   

     In the expanding universe, the Hubble constant is the 
ratio of the velocity of recession of galaxies to their 
distances.  The dynamic, ever-changing age of the universe 
can be estimated from the Hubble constant.  From their 
observations, Freedman's team has concluded that the Hubble 
constant has a value of 80 kilometers per second per mega  
parsec (1 parsec equals 3.26 light years), with an estimated 
uncertainty of plus or minus 17 kilometers per second.  That 
makes the universe younger than the generally held estimate 
of about 20 billion years old.   

     The new estimate of age brings into question other age 
estimates, the astronomers contend, including stellar 
evolution dating of globular star clusters and the 
timescales thought to be necessary for the formation of 
large-scale structures in galaxies throughout the universe.

     The science observations were made as part of one of 
several key project priorities using the Hubble Space 
Telescope.  The project, called the Extragalactic Distance 
Scale Key Project, is discovering Cepheids in a variety of 
important galaxies in order to determine their individual 
distances and to arrive at an accurate value of the Hubble 
constant in general.  

     The relative ease with which the discovery of Cepheids 
in M100 was accomplished now suggests to the scientific 
community that the Hubble telescope may be able to determine 
distances to remote galaxies that were before inaccessible 
because they had been blurred and distorted by the Earth's 
atmosphere. 

     "The Cepheid variables in M100 popped out at us like 
sparkling gems when we were reviewing the images, telling us 
that we will probably be able to use the telescope to 
observe galaxies as far as 150 million light-years away," 
Madore said.  

     "Hubble is also allowing us to make observations in a 
few short months that used to take a decade or more to 
complete," he added.  "At this rate, we're going to find the 
answer to the Hubble constant in our lifetimes." 

     The Wide Field and Planetary Camera-2 -- the primary 
imaging camera on board the Hubble Space Telescope -- was 
built by JPL for NASA's Office of Space Science, Washington, 
D.C.

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10/26/94 DEA
#9464