Oct. 17, 2007

Grey Hautaluoma
Headquarters, Washington 
202-358-0668
grey.hautaluoma-1@nasa.gov

Robert Naeye
Goddard Space Flight Center, Greenbelt, Md.
301-286-4453
robert.p.naeye@nasa.gov

RELEASE: 07-227

NASA CONCLUDES SUCCESSFUL FUSE MISSION

WASHINGTON - After an eight-year run that gave astronomers a 
completely new perspective on the universe, NASA has concluded the 
Far Ultraviolet Spectroscopic Explorer mission. The satellite, known 
as FUSE, became inoperable in July when the satellite lost its 
ability to point accurately and steadily at areas of interest. NASA 
will terminate the mission Oct. 18.

"FUSE accomplished all of its mission goals and more," said Alan 
Stern, associate administrator for the Science Mission Directorate at 
NASA Headquarters, Washington. "FUSE vastly increased our 
understanding of our galaxy's evolution and many exotic phenomena and 
left a strong legacy on which to build the next generation of 
investigations and missions."

Launched in 1999, FUSE helped scientists answer important questions 
about the conditions in the universe immediately following the Big 
Bang, how chemicals disperse throughout galaxies, and the composition 
of interstellar gas clouds that form stars and solar systems. 

"FUSE helped pioneer low-cost, principal investigator-led astronomy 
missions," said Jon Morse, director of the Astrophysics Division at 
NASA Headquarters. 

Examples of the many successes FUSE achieved during its mission are:

- By measuring abundances of molecular hydrogen (made of two hydrogen 
atoms), FUSE showed that a large amount of water has escaped from 
Mars, enough to form a global ocean 100 feet deep. 

- FUSE observed a debris disk that is surprisingly rich in carbon gas 
orbiting the young star Beta Pictoris. The carbon overabundance 
indicates either the star is forming planets that could end up as 
exotic, carbon-rich worlds of graphite and methane, or Beta Pictoris 
is revealing an unsuspected phenomenon that also occurred in the 
early solar system. 

- FUSE discovered far more deuterium, a form of hydrogen with a proton 
and a neutron instead of just one proton, in the Milky Way galaxy 
than astronomers had expected. Deuterium was produced in the early 
universe, but this isotope is destroyed easily in stellar nuclear 
reactions. "FUSE showed that less deuterium has been burned in stars 
over cosmic time, in agreement with modern models for the evolution 
of the galaxy and the recent Wilkinson Microwave Anisotropy Probe 
results," said Warren Moos, FUSE principal investigator, Johns 
Hopkins University, Baltimore.

- FUSE saw that an atmosphere of very hot gas surrounds the Milky Way. 
The ubiquity of hot gas around our galaxy demonstrates the galaxy is 
even more dynamic than expected. 

- By detecting highly ionized oxygen atoms in intergalactic space, 
FUSE showed that about 10 percent of matter in the local universe 
consists of million-degree gas floating between the galaxies. This 
discovery might help resolve the long-standing mystery of the 
universe's "missing baryons." Baryons are subatomic particles, often 
protons and neutrons. Calculations of how many baryons were produced 
in the very early universe predict about twice as many baryons as 
astronomers have observed. The rest of the missing baryons might 
exist as even hotter gas, which could be observed by future X-ray 
observatories such as NASA's Constellation-X. 

"FUSE collected quality science data for eight years, longer than its 
five-year goal. By any measure, FUSE was a success," said George 
Sonneborn, FUSE project scientist at NASA's Goddard Space Flight 
Center, Greenbelt, Md. 

Although FUSE's mission has ended, NASA's ultraviolet study of the 
universe continues. In 2008, NASA will conduct a servicing mission to 
the Hubble Space Telescope to install a new ultraviolet spectrograph 
on the telescope and repair another. The new Cosmic Origins 
Spectrograph, or COS, is designed to study remote galaxies and nearby 
stars in the ultraviolet. Hubble's Space Telescope Imaging 
Spectrograph also will be repaired. That instrument had ultraviolet 
capabilities complementary to the COS and was used in conjunction 
with FUSE when both were operational. The spectrograph failed due to 
an electronic short in August 2004 after more than seven years of 
in-orbit operations.

FUSE was a joint mission of NASA, the Canadian Space Agency and the 
French Space Agency, the Centre National d'Etudes Spatiales. The 
Johns Hopkins University built the telescope and managed the mission. 
The University of Colorado, Boulder, built FUSE's spectrograph. The 
University of California, Berkeley, made the detectors. For more 
information, visit:

http://fuse.pha.jhu.edu 

	
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