Princeton, N.J. — Their pride and joy is about to leave home, travel far and,
if all goes well, send back reports of great sights.
It’s not a graduation. It’s a satellite launch.
On June 30, Princeton scientists will participate as NASA launches a satellite
carrying a powerful scientific instrument that the University played a large
role in conceiving, designing, and building.
The great sight it is intended to glimpse is nothing less than the infancy of
the universe. The satellite will measure something called cosmic microwave
background radiation — a faint trickle of energy that is essentially the echo
of the Big Bang itself.
“We’re getting a snapshot of what the universe looked like 300,000 years
after the Big Bang,” said Princeton astrophysicist David Spergel, a project
scientist. That’s a long time ago, considering that the universe is thought to
be somewhere around 14 billion years old. It’s the equivalent of looking into
the eyes of an 80-year-old man and seeing what he looked like 15 hours after
birth.
The message scientists will take from this report is expected to answer some
of the most fundamental and longstanding questions in cosmology, such as the
age of the universe, what it is made of and how fast it is expanding.
To do so, the satellite, called MAP, or Microwave Anisotropy Probe, will
measure exceedingly small variations — anisotropies — in the nearly uniform
flow of background radiation. Reading the spacing of these ripples will tell
scientists how long it has been since they began spreading out, like waves
from a rock thrown into a pool, and thus how long it has been since the Big
Bang.
The pursuit of this information will take MAP far from home. The rocket
leaving Cape Canaveral will carry the satellite not into a conventional orbit
around Earth, but to a spot a million miles away where it will orbit the sun.
This destination, called the Lagrange point No. 2, is unique in that the
combined gravity of the Earth and sun will keep the satellite in lockstep
with the Earth, always forming a straight line from sun to Earth to satellite.
This vantage point, unoccupied by any other satellite, is relatively free
of radiation and other interference. “It’s a nice quiet place to be,” said
Spergel.
The probe will take three months to reach the Lagrange point and six months
to collect data. The first analysis should be available near the end of 2002.
The launch is set for 3:46:46 p.m. on June 30 at Cape Canaveral, but the
possible launch “window” extends to July 5 in the event of problems or bad
weather.
The quest to measure cosmic background radiation is a long-time pursuit at
Princeton. Bell Labs scientists Arno Penzias and Robert Wilson won the Nobel
Prize for discovering the radiation in 1965, but Princeton physicist David
Wilkinson, using a device atop Guyot Hall, made a nearly simultaneous
observation that confirmed the Penzias-Wilson discovery.
Wilkinson has been a leader in studying the microwave background, developing
many probes that have established increasingly accurate measurements. He was
one of the principal scientists behind MAP’s predecessor, called COBE, which
confirmed the presence of anisotropies in the radiation. MAP will have 30
times the resolution of COBE, with 20 individual measuring devices compared
to COBE’s six.
The MAP project began in 1996 when NASA accepted a proposal for the satellite
to be built in a partnership between NASA Goddard Space Flight Center in
Greenbelt, Md. and Princeton University. The team includes colleagues from
Goddard, the University of Chicago, University of California-Los Angeles,
the University of British Columbia and Brown University. The groups worked
closely on the design and construction of the probe. NASA has spent $145
million on the project.
Highly skilled machinists in the University’s physics department machine shop
crafted part of the sensitive measuring device here in Princeton. The whole
assemblage will be launched into space on a Boeing Delta II rocket.
The instrument has gone through extensive testing at Goddard, including the
simulation of the extremely cold conditions of space and the tremendous
vibration of a rocket launch. Final tests are continuing, even as the
satellite moves to the launch pad in Florida. But with most of the work
behind them, the Princeton scientists are thrilled and eager for a safe
lift-off.
“It’s fantastic,” said Princeton physicist Lyman Page. “We’re getting very
excited now.”
Further information on the MAP project is available at
http://map.gsfc.nasa.gov/index.html
