NASA's Swift satellite
was successfully launched Saturday aboard a Boeing Delta 2 rocket
at 12:16 p.m. EST from Launch Complex 17A at the Cape Canaveral Air
Force Station, Fla. The satellite will pinpoint the location of
distant yet fleeting explosions that appear to signal the births of
black holes.
About 80 minutes after launch, the spacecraft was successfully
separated from the Delta second stage. It has also been confirmed
that the solar arrays are properly deployed.
"It's a thrill that Swift is in orbit. We expect to detect and
analyze more than 100 gamma-ray bursts a year. These are the most
powerful explosions in the universe, and I can't wait to learn more
about them," said Swift Principal Investigator Dr. Neil Gehrels, at
NASA's Goddard Space Flight Center, Greenbelt, Md.
Each gamma-ray burst is a short-lived event, lasting only a few
milliseconds to a few minutes, never to appear again. They occur
several times daily somewhere in the universe, and Swift should
detect several weekly.
Swift, a mission with international participation, was designed
to solve the 35-year-old mystery of the origin of gamma-ray bursts.
Scientists believe the bursts are related to the formation of black
holes throughout the universe - the birth cries of black holes.
To track these mysterious bursts, Swift carries a suite of three
main instruments. The Burst Alert Telescope (BAT) instrument, built
by Goddard, will detect and locate about two gamma-ray bursts
weekly, relaying a rough position to the ground within 20 seconds.
The satellite will swiftly re-point itself to bring the burst area
into the narrower fields of view of the on-board X-ray Telescope
(XRT) and the UltraViolet/Optical Telescope (UVOT). These
telescopes study the afterglow of the burst produced by the cooling
ashes that remain from the original explosion.
The XRT and UVOT instruments will determine a precise arc-second
position of the burst and measure the spectrum of its afterglow
from visible to X-ray wavelengths. For most of the bursts detected,
Swift data, combined with complementary observations conducted with
ground-based telescopes, will enable measurements of the distances
to the burst sources.
The afterglow phenomenon can linger in X-ray light, optical
light, and radio waves for hours to weeks, providing detailed
information about the burst. Swift will check in on bursts
regularly to study the fading afterglow, as will ground-based
optical and radio telescopes. The crucial link is having a
precise location to direct other telescopes. Swift will provide
extremely precise positions for bursts in a matter of minutes.
Swift notifies the astronomical community via the
Goddard-maintained Gamma-ray Burst Coordinates Network. The Swift
Mission Operations Center, operated from Penn State's University
Park, Pa., campus, controls the Swift observatory and provides
continuous burst information.
"Swift can respond almost instantly to any astrophysical
phenomenon, and I suspect that we're going to be making many
discoveries which are currently unpredicted," said Swift Mission
Director John Nousek, Penn State professor of astronomy and
astrophysics.
Goddard manages Swift. Swift is a NASA mission with the
participation of the Italian Space Agency (ASI) and the Particle
Physics and Astronomy Research Council in the United Kingdom.
Swift was built through collaboration with national
laboratories, universities and international partners, including
General Dynamics, Gilbert, Arizona; Penn State University; Los
Alamos National Laboratory, New Mexico; Sonoma State University,
Rohnert Park, Calif.; Mullard Space Science Laboratory in Dorking,
Surrey, England; the University of Leicester, England; ASI-Malindi
ground station in Africa; the ASI Science Data Center in Italy; and
the Brera Observatory in Milan, Italy.