For release at 10 a.m. EDT April 29, 2001
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South Pole experiment supports inflation theory of universes origin, measures density of ordinary and dark matter in universe
The leading theory regarding the origin of the universe has just passed another major test, one posed by University of Chicago astronomers and their colleagues working at a National Science Foundation observatory at the South Pole.
The theory, called cosmic inflation, proposes that the universe underwent a gigantic growth spurt in a fraction of a second just moments after the big bang. According to inflation, the largest structures in the universe trace their origins to the fundamental fuzziness of the subatomic world.
Inflation created tiny lumps in the distribution of matter and tiny variations in the temperature of the cosmic microwave background, the afterglow of the big bang, sowing the seeds that stretched the fuzziness of the subatomic world to cosmic scales.
With these new data, inflation looks very strong, said John Carlstrom, the S. Chandrasekhar Distinguished Service Professor in Astronomy & Astrophysics at the University of Chicago. Its always been theoretically compelling. Now its on very solid experimental ground.
Carlstrom leads a team of astrophysicists working with the $3 million Degree Angular Scale Interferometer (DASI) at the NSFs Center for Astrophysical Research in Antarctica. The team, which consists of the University of Chicagos Nils Halverson, Clem Pryke, Erik Leitch, and John Kovac, and colleagues at the California Institute of Technology, University of California, Berkeley, and Caltechs Jet Propulsion Laboratory, will present its first results from DASI Sunday, April 29, at the American Physical Society meeting in Washington, D.C.
The thing I find exciting about this field is that you have theoretical models of the entire universe becoming testable, said Pryke, a Chicago Research Scientist. You can do an experiment and match up the results against these models. Twenty years ago, by contrast, experimental technology limited cosmological theories like inflation strictly to the theoretical domain.
When introduced in the early 1980s, inflation predicted that astronomers should see a pattern of temperature differences in the cosmic microwave background radiation, which pervades the sky. DASI, a highly sensitive interferometer, can measure these subtle temperature variations at an angular resolution of one-tenth of a degree across the sky, about a fifth of the moons angular size.
DASI detects these temperature differences at a time when the universe, now approximately 14 billion years old, was only 400,000 years old. These temperature differences show up in DASIs data as a ripple pattern that displays as many as three progressively fainter peaks in the blast waves emanating from the big bang.
The inflation model predicts this series of peaks. Two previous experiments have already detected the large first peak, which indicates that the geometry of the universe is flat. This means that light travels in straight lines rather than on curved trajectories.
DASI sees the first two peaks and strongly suggests a third peak, Carlstrom said. If no peaks had shown up, inflation would have difficulties. We'd be back to the drawing board.
The ratio of the intensity between the first and second peaks tells scientists how much ordinary matter exists in the universe. The DASI data indicate that ordinary matter, the stuff of which humans, stars and galaxies are made, accounts for only 4.5 percent of the universes total mass and energy. Astrophysicists know that eight times as much dark matter exists in the universe. The DASI result strengthens the case that most of the mysterious dark matter is comprised of some new form of matter, said Michael Turner, the Bruce and Diana Rauner Distinguished Service Professor at the University of Chicago. We may be made of star stuff, but we are not made of the stuff of the cosmos.
The 4.5 percent figure agrees with the estimate of ordinary matter that Turner and David Schramm published in 1998 using a completely different method based on the amount of deuterium produced in the big bang.
The University of Chicagos Schramm, who died in 1997, was among the first to realize that deuterium was a sensitive indicator of the density of ordinary matter in the universe, Turner said. The agreement between measures of the amount of ordinary matter is simply stunning, Turner said. The underlying physics is completely different. The big bang framework and Einsteins general relativity have passed a major new test.
Even though astrophysicists have nearly nailed down the validity of inflation, more work remains.
This is just the beginning, Turner said. Further data will come from DASI and its sister instrument, the California Institute of Technologys Cosmic Background Imager, as well as the University of Chicagos TopHat experiment and NASAs Microwave Anisotropy Probe.
Not only will we be able to test inflation, but we will be able to learn about its underlying physical cause, he said.
Last modified at 01:55 PM CST on Friday, September 12, 2003.
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