William Steigerwald
NASA Goddard Space Flight Center
301 286 5017
wsteiger@pop100.gsfc.nasa.gov

Michael Purdy
The Johns Hopkins University News Office
410 516 7906
mcp@jhu.edu

Dr. Alain Lecavelier
Institut d'Astrophysique de Paris
Tel: (33-1) 44 32 80 77
Fax: (33-1) 44 32 80 01
lecaveli@iap.fr

EMBARGOED UNTIL 2:00 P.M. EDT WEDNESDAY 15 AUGUST 2001

FUSE SEES SOLAR SYSTEM UNDER CONSTRUCTION

A nearby young star recently gave birth to millions of comets, 
according to new observations using NASA's Far Ultraviolet 
Spectroscopic Explorer (FUSE) spacecraft. The result provides clues 
to how our own solar system formed and evolved.

The star, Beta Pictoris, is estimated to be about 20 million years 
old, relatively young for a star whose life will span billions of 
years.  It is about 60 light years from Earth, in the direction of 
the southern constellation Pictor (Painter's Easel). (One light year 
is almost 6 trillion miles, or about 9.6 trillion kilometers.) A 200 
billion-mile diameter disk of dust and gas surrounds Beta Pictoris, 
and previous observations have given hints that planets may be 
forming (or recently formed) deep within.

The new research by an international team of astronomers shows how 
the chemistry of the disk implies that comets have formed around Beta 
Pictoris as well, and gives additional evidence that these comets are 
evaporating by the millions. The journal Nature will publish this 
research August 16.

"We are very excited about these observations because they are a rare 
glimpse at the chaotic birth of a solar system," said Dr. George 
Sonneborn, FUSE Project Scientist at NASA's Goddard Space Flight 
Center. "Young planetary systems are surprisingly active; we are 
witnessing the birth and evaporation of millions and millions of 
comets."

A team of scientists from the Institut d'Astrophysique de Paris-CNRS 
(IAP, France) led by Dr. Alain Lecavelier des Etangs, together with 
colleagues from the Johns Hopkins University (Baltimore, MD), and the 
Laboratoire d'Astrophysique de Marseille (France), has found no 
evidence of molecular hydrogen (H2), the most abundant molecule in 
the universe, in the Beta Pictoris disk. This was unexpected because 
the same team, using the Hubble Space Telescope, had previously found 
carbon monoxide (CO) in the Beta Pictoris disk.  What is seen in the 
Beta Pictoris system is thus contrary to what is commonly seen in the 
gaseous clouds of our galaxy, where CO is only seen when H2 is 
present. When these clouds collapse, they form new stars and 
planetary systems; thus, they are the raw material for new solar 
systems like Beta Pictoris.

"In interstellar gas clouds, carbon monoxide gets broken apart by 
starlight in about 1,000 years, a relatively short time compared to 
the estimated 20 million-year age of Beta Pictoris. Since we still 
see carbon monoxide, we think the amount originally present in the 
cloud that formed Beta Pictoris is now locked up in some kind of 
reservoir where it is shielded from starlight as it is slowly 
released back into the Beta Pictoris disk," said Dr. Alfred 
Vidal-Madjar of IAP.

"Add this to the fact that the amount of molecular hydrogen is too 
low to be seen by FUSE. This is strange because normally there are 
about 100,000 molecular hydrogen molecules for every carbon monoxide 
molecule in interstellar gas clouds. So we think the molecular 
hydrogen has been locked away in some kind of reservoir also," said 
Lecavelier.

According to the researchers, comets, which consist largely of frozen 
gasses, are a likely reservoir. "In our own solar system, there is a 
swarm of thousands, perhaps millions, of comets beyond the orbit of 
Pluto, called the Kuiper belt. If a similar comet swarm surrounds 
Beta Pictoris, the comets would still be warm enough to slowly 
release carbon monoxide, but far too cold to release molecular 
hydrogen, which would remain locked up as water ice (H2O)," said Dr. 
Paul Feldman of the Johns Hopkins University.

FUSE uncovered new mysteries in the Beta Pictoris disk as well. "It 
gets really exciting when we compare our result to others," said 
Feldman. "Previous observations of infrared emission from Beta 
Pictoris with the Infrared Space Observatory actually contradict our 
lack of detection of ultraviolet absorption by molecular hydrogen 
along a narrow line-of-sight to the star. They claim to have detected 
a large amount of molecular hydrogen in the disk. If both results are 
correct, the only way for this conflict to be resolved is if the 
molecular hydrogen is not evenly distributed throughout the disk."

Molecular hydrogen absorbs certain kinds of ultraviolet light; when 
it does so, FUSE can detect its presence, but molecular hydrogen has 
to be more or less evenly distributed in a cloud to block ultraviolet 
light from stars behind the cloud, or it won't reveal itself to FUSE. 
However, molecular hydrogen can also emit infrared light; celestial 
objects containing molecular hydrogen will glow in infrared if they 
are warm enough, and can be seen directly by the Infrared Space 
Observatory, depending on how close they are and how brightly they 
glow.

"The molecular hydrogen clumps could be left over gas from the 
formation of the star, or perhaps from failed protoplanets. The 
initial carbon monoxide would no longer be in gaseous form but 
rather condensed into cometesimals or comets. All we can say for 
certain is that carbon monoxide must be continuously generated in 
the disk," said Feldman.

FUSE is a NASA Origins mission developed and operated by The Johns 
Hopkins University in collaboration with NASA's Goddard Space Flight 
Center, the Centre National d'Etudes Spatiales (France), the Canadian 
Space Agency, the University of Colorado, and the University of 
California, Berkeley.  FUSE was launched on June 24, 1999, from Cape 
Canaveral on a three-year mission to obtain high resolution spectra 
in the far ultraviolet wavelength region (905-1185 Angstroms) of 
faint objects within and beyond our galaxy.

  For more information about FUSE, refer to:
  http://fuse.pha.jhu.edu

For images of the Beta Pictoris disk, refer to:
http://www.iap.fr/betapic/images/images_index_e.html
http://oposite.stsci.edu/pubinfo/PR/96/02.html

Planet-forming disks around other stars:
http://oposite.stsci.edu/pubinfo/pr/1999/03/index.html
http://oposite.stsci.edu/pubinfo/PR/1999/05/index.html