NASHVILLE, Tenn. – The most ambitious attempt yet to trace the history of the universe has seen "first light." The Baryon Oscillation Spectroscopic Survey (BOSS), part of the Sloan Digital Sky Survey III (SDSS-III), took its first astronomical data on the night of Sept. 14-15 at the Sloan Foundation telescope in New Mexico.
The goal of the six-year project is to measure the spectra of 1.4 million galaxies and 160,000 quasars, extremely distant objects that shine more brightly than entire galaxies. The previous sky survey (SDSS-II) determined the two-dimensional position of these objects in the sky. The new project will measure their distance, allowing astronomers to produce a three-dimensional map with unprecedented detail that extends out about one-fifth of the full depth of the visible universe and traces the evolution of the universe back some 6.5 billion years.
"This will give us a three-dimensional map of a large volume of the universe, which is exactly what we need to learn more about dark energy," said assistant professor Andreas Berlind. He and his colleagues in Vanderbilt's physics and astronomy department – assistant professor Kelly Holley-Bockelman, associate professor Keivan Stassun and professor David Weintraub – are participating in the survey along with 350 scientists from 41 other institutions.
Dark energy is a type of "negative gravity" that seems to play a role in accelerating the expansion of the universe. Scientists think it makes up about 70 percent of the energy/matter of the universe but its basic nature is a mystery. "One of the most sensitive measures of dark energy that we have found is the large-scale distribution of galaxies," Berlind said.
BOSS uses the same telescope as the original Sloan Digital Sky Survey, but it has been equipped with new, specially built spectrographs. The new instruments can measure the spectra of 1,000 objects at a time and are considerably more sensitive than the original instruments so they can record the spectra of extremely dim objects. "The new spectrographs are much more efficient in infrared light," explained Natalie Roe of Berkeley Lab, the instrument scientist for BOSS. "The light emitted by distant galaxies arrives at Earth as infrared light, so these improved spectrographs are able to look much farther back in time."
The Vanderbilt team brings a unique resource to the project: A set of more than 400 simulated universes. These are computer models of the universe that start at the Big Bang and then virtually evolve to the present following known physical laws. "Other groups have produced individual simulations that are more detailed than ours, but we've gone for greater numbers in order to get a better idea of the amount of variation that is possible," said Berlind.
These virtual universes are being used to test the BOSS data analysis methods and will be necessary to interpret BOSS's measurements of dark energy. Berlind and his colleagues are generating simulated observational data from a number of their virtual universes; this data is run through the BOSS analysis pipeline and the results are compared with the original. "This allows us to catch any systematic errors that might throw the results off," he said.
Source: Vanderbilt University