FOR RELEASE:  May 9, 1996

CONTACT:  Don Savage                                  
          NASA Headquarters, Washington, DC
          (Phone: 202-358-1547)

          Tammy Jones
          Goddard Space Flight Center, Greenbelt, MD
          (Phone: 301-286-5566)

          Ray Villard
          Space Telescope Science Institute, Baltimore, MD
          (Phone: 410-338-4514)

PRESS RELEASE NO.: STScI-PR96-21


          HUBBLE SPACE TELESCOPE ON TRACK FOR MEASURING
                  THE EXPANSION OF THE UNIVERSE

Two international teams of astronomers, using NASA's Hubble Space Telescope,
are reporting major progress in converging on an accurate measurement of the
Universe's rate of expansion -- a value which has been debated for over half a
century.

These new results yield ranges for the age of the Universe from 9-12 billion 
years, and 11-14 billion years, respectively.  The goal of the project is to 
measure the Hubble Constant to ten percent accuracy.

The Hubble Space Telescope Key Project team, an international group of over 20
astronomers, is led by Wendy Freedman of Carnegie Observatories, Pasadena, CA,
Robert Kennicutt, University of Arizona, Tucson, AZ, and Jeremy Mould, Mount
Stromlo and Siding Springs Observatory, Australia.  The group's interim
results, announced at a meeting held at the Space Telescope Science Institute 
(STScI) in Baltimore, Maryland, are consistent with their preliminary result, 
announced in 1994, of 80 kilometers per second per megaparsec (km/sec/Mpc), 
based on observations of a galaxy in the Virgo cluster.  

"We have five different ways of measuring the Hubble Constant with HST," said
Dr. Freedman.   "The results are coming in between 68 and 78 km/sec/Mpc." 
(For example, at an expansion rate of 75 km/sec/Mpc, galaxies appear to be 
receding from us at a rate of 162,000 miles per hour for every 3.26 million 
light-years farther out we look).

Two months ago, a second team, led by Allan Sandage, also of the Carnegie
Observatories, Abhijit Saha, STScI, Gustav Tammann and Lukas Labhardt, 
Astronomical Institute, University of Basel, Duccio Macchetto and Nino Panagia,
STScI/European Space Agency, reported a slower expansion rate of 57 km/sec/Mpc. 
 
The value of the Hubble Constant allows astronomers to calculate the expansion
age of the Universe, the time elapsed since the Big Bang.  Astronomers have
been arguing recently whether the time since the Big Bang is consistent with
the ages of the oldest stars. 

The ages are calculated from combining the expansion rate with an estimate of
how much matter is in space.  The younger age values from each team assume the
Universe is at a critical density where it contains just enough matter to
expand indefinitely.  The higher age estimates are calculated based on a low
density of matter in space.  (See "Science Background" for more information on
the expanding Universe.)

"A point of great interest is whether the age of the Universe arrived at this
way is really older than the independently derived ages of the oldest stars,"
said Saha, an investigator on both Hubble teams. 

"The numbers lean on the side that the stellar ages are a little lower, or
that the hypothesis that we live in a critical density universe needs to be
questioned," said Saha.  "As further results accumulate over the next few
years, we hope to tighten the constraints on these issues."


THE OBSERVATIONS

The Key Project team is midway along in their three-year program to derive the
expansion rate of the Universe based on precise distance measurements to
galaxies.  They have now measured Cepheid distances to a dozen galaxies, and
are about halfway through their overall program.

The Key Project team also presented a preliminary estimate of the distance to
the Fornax cluster of galaxies.  The estimate was obtained through the
detection and measurement with the Hubble Space Telescope of pulsating stars
known as Cepheid variables found in the Fornax cluster.  The Fornax cluster is
measured to be approximately as far away as the Virgo cluster of galaxies --
about 60 million light-years. 

The Key Project team member who led this effort, Caltech astronomer Barry
Madore said, "This cluster allows us to make independent estimates of the
expansion rate of the Universe using a number of different techniques.  All of
these methods are now in excellent agreement.  With Fornax we are now at
turning point in this field."   

The team is measuring Cepheid distances to the Virgo and Fornax clusters 
of galaxies as a complementary test.  Their strategy is to compare and contrast 
expansion numbers from a variety of distance indicators.

The Key Project team is systematically looking into a variety of methods for
measuring distances.  They are using Cepheids in a large sample to tie into 
five or six "secondary methods".  One such secondary method relates the total
luminosity of a galaxy to the rate at which the galaxy is spinning, the
Tully-Fisher relation.  Another secondary method makes use of a special class
of exploding star known as a type Ia supernova.  This phase of the Hubble 
Constant research will be completed within another two years.

In contrast, the Sandage team focused on a single secondary distance
indicator, one of the same indicators also used by the Key Project team, the
type Ia supernova.  Sandage maintains that these stars are "standard bombs"
according to theory.  He suggests that when they explode they all reach
exactly the same intrinsic brightness.  This would make them extremely
reliable "standard candles," (objects with a well-known intrinsic brightness)
visible 1,000 times farther away than Cepheids.  Since they are intrinsically
brighter than any other standard candle, they offer the opportunity for an
accurate measurement of the Universe's overall expansion by looking out the
farthest. 

Although both teams are still in disagreement over the precise rate at which
the Universe is expanding and on how old it is, they are optimistic that their
estimates will continue to converge with further observations and analysis.

                                  * * * *

Members of the Key Project team include W. Freedman (Carnegie Observatories),
R. Kennicutt (University of Arizona), J. Mould (Mount Stromlo and Siding
Springs Observatories, Australia), L. Ferrarese (Johns Hopkins University), 
H. Ford (Johns Hopkins University), J. Graham (Department of Terrestrial
Magnetism), M. Han (University of Wisconsin), P. Harding (University of
Arizona), J. Hoessel (University of Wisconsin), J. Huchra (Smithsonian/Harvard
University), S. Hughes (Royal Greenwich Observatory, Cambridge), 
G. Illingworth (University of California, Santa Cruz), B.F. Madore
(IPAC/Caltech), R. Phelps (Carnegie Observatories), A. Saha (Space Telescope
Science Institute), N. Silbermann (IPAC), P. Stetson (Dominion Astrophysical
Observatory), and S. Sakai (IPAC).

Members of the Sandage team include A. Sandage (Carnegie Observatories), 
A. Saha (Space Telescope Science Institute), G.A. Tammann, and L. Labhardt 
(Astronomical Institute, University of Basel), F.D. Macchetto and N. Panagia
(Space Telescope Science Institute/European Space Agency).

The Space Telescope Science Institute is operated by the Association of
Universities for Research in Astronomy, Inc. (AURA), for NASA, under contract
with the Goddard Space Flight Center, Greenbelt, MD.  The Hubble Space
Telescope is a project of international cooperation between NASA and the
European Space Agency (ESA).


Image files in GIF and JPEG format and captions may be accessed on Internet
via anonymous ftp from ftp.stsci.edu in /pubinfo.
                              GIF                 JPEG
PRC96-21a      NGC 1365       gif/NGC1365.gif     jpeg/NGC1365.jpg
PRC96-21b      NGC 4639       gif/NGC4639.gif     jpeg/NGC4639.jpg

Higher resolution digital versions (300dpi JPEG) of the release photographs
will be available temporarily in /pubinfo/hrtemp: 96-21a.jpg and 96-21b.jpg
(color) and 96-21abw.jpg and 96-21bbw.jpg (black/white).  

GIF and JPEG images, captions and press release text are available via World
Wide Web at URLs:
http://www.stsci.edu/pubinfo/PR/96/21.html and via links in:
http://www.stsci.edu/pubinfo/Latest.html or 
http://www.stsci.edu/pubinfo/Pictures.html


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SCIENCE BACKGROUND -
CLOSING IN ON UNDERSTANDING THE EXPANDING UNIVERSE


WHAT'S THE DIFFERENCE BETWEEN AN OPEN AND CLOSED UNIVERSE?

An open universe expands forever; a closed universe expands, but
decelerates until it eventually reverses direction and begins to
contract; a "critical density" universe is exactly midway between these
scenarios and so will expand indefinitely, always slowing down but
never quite coming to a halt.  If, for example, you throw an object up
in the air, it falls down due to gravity.  But if the object moves fast
enough (say, by rocket) it can escape from the Earth.  By analogy the
Universe itself may not have enough density to halt its own expansion.


WHAT'S THE RELATIONSHIP BETWEEN MASS DENSITY AND AGE OF THE UNIVERSE?

The rate of the Universe's expansion reflects how much gravity and
hence, matter, it has.  Like going up a steep hill, the galaxies
outward rush should have slowed if the Universe has a lot of mass, and
this implies a younger universe.  If the Universe has little mass, and
so is barely decelerating, then galaxies would have taken more time to
reach their current positions, like rolling along a flat floor.

The rate of the Universe's expansion should be slowed by the mutual
gravitational pull of all matter contained in the Universe.


WHY DO THEORISTS FAVOR A CRITICAL DENSITY UNIVERSE?

In formulating the simplest models of the expanding universe theorists
favor the notion that space contains the exact amount of matter that
keeps the Universe precisely balanced between expanding forever and
collapsing under gravity.  Assuming such a "critical density" makes it
easier to explain a number of observed properties of the space,
including the large-scale structure of galaxies.


DOES THE UNIVERSE CONTAIN ENOUGH MASS TO REACH CRITICAL DENSITY?

A fundamental problem is that telescopic observations show that the
Universe contains only 1/100 the luminous (i.e., stars and galaxies)
mass that it needs to reach critical density.  Astrophysicists hold
that dark matter must account for the rest.  Observational evidence
showing that dark matter affects the rotation rate of galaxies, and
behavior of clusters of galaxies, boosts estimates of the amount of
matter in the Universe to 10% of the value needed to reach critical
density.  To date the remaining 90% of the required mass to reach
critical density is missing and unaccounted for.


WHY HAS IT TAKEN MORE THAN 60 YEARS FOR ASTRONOMERS TO CALCULATE AN
ACCURATE VALUE FOR THE HUBBLE CONSTANT?

First, astronomers discovered that establishing an accurate distance
scale to faraway galaxies has been more difficult than anticipated.
Second, while astronomers can simply and accurately measure a galaxy's
velocity, the measurement may not represent the expansion velocity of
the Universe at that distance.  The reason is that each galaxy
possesses a gravitational force.  Velocities are altered when more
massive galaxies, which have stronger gravitational forces, pull
smaller galaxies toward them.


WHY ARE THE TEAMS OPTIMISTIC THEY ARE CONVERGING ON A SINGLE VALUE FOR
THE HUBBLE CONSTANT?

The historically debated values of the expansion rate of the Universe
have differed by up to a factor of two, but the estimates of the two
Hubble teams are now within 25 percent.  Hubble Space Telescope has
taken this decades-old debate out of gridlock and on toward a
solution.   That's because Hubble can see and measure certain key
celestial distance markers out to ten times farther from Earth than
ground-based telescopes.


HOW DO THE TEAMS MEASURE COSMIC DISTANCES?

Both teams base their results on studying a class of celestial milepost
marker, called Cepheid variable stars, whose pulsation rate is a direct
indication of their intrinsic brightness.

Freedman's team is systematically looking into a variety of methods for
measuring distances.  They are using Cepheids in a large sample to tie
into five or six "secondary methods."  One such secondary method
relates the total luminosity of a galaxy to the rate at which the
galaxy is spinning, the Tully-Fisher relation.  Another secondary
method makes use of a special class of exploding star known as a type
Ia supernova.  These secondary distance indicators are needed to look
deeper into the Universe to get a more representative rate for the
expansion of space (the gravitational fields of nearby clusters may
yield an inaccurate value because the expansion rate may be affected by
the local motion of galaxies).

In contrast, the Sandage team took the "fast track" to focus on a
single secondary distance indicator, one of the same indicators also
used by the Key Project Team, the type Ia supernova.  Sandage maintains
that these stars are "standard bombs" that all reach exactly the same
intrinsic brightness.  They are visible 1,000 times farther away than
Cepheids, allowing for an accurate measurement of the Universe's
overall expansion.


WHY IS OBSERVING THE FORNAX GALAXY CLUSTER IMPORTANT?

Earlier results derived from the Virgo cluster have been questioned
because that cluster is so large that possible inaccuracies in the
distances of individual galaxies from its center might affect some
findings.  The Fornax cluster is more compact than the Virgo cluster,
so there is much less range for uncertainty in the distances of member
galaxies from its center.