Radio astronomers develop new technique for studying dark energy
Sound waves in the early universe are thought to have left detectable imprints on the large-scale distribution of galaxies. The researchers developed a way to measure such imprints by observing the radio emission of hydrogen gas.
Provided by NRAO, Socorro, New Mexico
July 21, 2010
Pioneering observations with the National Science Foundation's giant Robert C. Byrd Green Bank Telescope (GBT) have given astronomers a new tool for mapping large cosmic structures. The method promises to provide valuable clues about the nature of the mysterious dark energy believed to constitute nearly three-fourths of the mass and energy of the universe.
Dark energy is the label scientists have given to what is causing the universe to expand at an accelerating rate. While the acceleration was discovered in 1998, its cause remains unknown. Physicists have competing theories to explain the acceleration, and they believe the best way to test those theories is to precisely measure large-scale cosmic structures.
Sound waves in the matter-energy soup of the early universe are thought to have left detectable imprints on the large-scale distribution of galaxies in the universe. The researchers developed a way to measure such imprints by observing the radio emission of hydrogen gas. Their technique, called intensity mapping, when applied to greater areas of the universe, could reveal how such large-scale structures have changed over the last few billion years, giving insight into which theory of dark energy is the most accurate.
"Our project mapped hydrogen gas to greater cosmic distances than ever before, and it shows that the techniques we developed can be used to map huge volumes of the universe in three dimensions and to test the competing theories of dark energy," said Tzu-Ching Chang from the Academia Sinica in Taiwan and the University of Toronto.
To get their results, the researchers used the GBT to study a region of sky that the Keck II telescope in Hawaii had previously surveyed in detail. This optical survey used spectroscopy to map the locations of thousands of galaxies in three dimensions. With the GBT, instead of looking for hydrogen gas in these individual, distant galaxies, the team used their intensity-mapping technique to accumulate the radio waves emitted by the hydrogen gas in large volumes of space, including many galaxies.
"Since the early part of the 20th century, astronomers have traced the expansion of the universe by observing galaxies. Our new technique allows us to skip the galaxy-detection step and gather radio emissions from a thousand galaxies at a time, as well as all the dimly-glowing material between them," said Jeffrey Peterson, from Carnegie Mellon University.
The astronomers also developed new techniques that removed both man-made radio interference and radio emission caused by more-nearby astronomical sources, leaving only the extremely faint radio waves coming from the very distant hydrogen gas. The result was a map of part of the "cosmic web" that correlated neatly with the structure shown by the earlier optical study. The team first proposed their intensity-mapping technique in 2008, and their GBT observations were the first test of the idea.
"These observations detected more hydrogen gas than all the previously detected hydrogen in the universe, and at distances 10 times farther than any radio wave-emitting hydrogen seen before," said Ue-Li Pen from the University of Toronto.
"This is a demonstration of an important technique that has great promise for future studies of the evolution of large-scale structure in the universe," said Chris Carilli from the National Radio Astronomy Observatory, Socorro, New Mexico.